MULTIOMIC ANALYSIS OF NANOPARTICLE-CORONAS

Abstract

The present invention relates to methods for simultaneously identifying and/or detecting distinct classes of biomarker in biofluid samples, such as blood.

Description

FIELD OF THE INVENTION

The present invention relates to methods for simultaneously identifying and/or detecting distinct classes of biomarker in biofluid samples, such as blood. Such method may be useful in analysing disease specific biomarkers. The method creates a nanoparticle-based liquid biopsy platform that simultaneously harvests multiple classes/families of molecules (including proteins, nucleic acids, and lipids) from a single biofluid sample and then analyzes these classes of molecules. Suitably, the biofluid is from a subject with or suspected of having a disease and the biomolecules analyzed are disease-specific biomarkers. In particular, the methods involve contacting nanoparticles with a biofluid from a subject, optionally in a diseased state, and subsequent multi-omic analysis of the biomolecule corona formed on said nanoparticles. In addition, the present invention relates to methods for monitoring cancer progression in a subject by assessing the type and/or amount of tumour-specific biomarkers from two or more classes simultaneously as measured over time.

INTRODUCTION

A biomarker, or biological marker, generally refers to a qualitative and/or quantitative measurable indicator of some biological state or condition. Biomarkers are typically molecules, biological species or biological events that can be used for the detection, diagnosis, prognosis and prediction of therapeutic response of diseases.

Ongoing efforts are focused on the development of robust and high-throughput ‘omics’ platforms for the discovery of minimally invasive molecular biomarkers to aid early and accurate cancer diagnosis, monitor tumour growth and response to therapies. Despite tremendous efforts and investment by major stakeholders, only few protein cancer biomarkers have been validated and received FDA approval, raising concerns regarding the efficiency of the biomarker-development pipeline, and of the FDA-approved biomarkers, the majority are used to monitor the progression of cancer, rather than enabling its early diagnosis.

Proteins are the biological endpoints that govern most pathophysiological processes and they and the nucleic acid that encode them have therefore attracted most interest so far as biomarkers for cancer diagnostics. Blood is the most valuable repertoire of cancer biomarkers; however, the discovery of tumour-derived protein signatures directly from blood is hindered by the wide concentration range of blood proteins, in addition to the preponderance of highly abundant proteins. The same challenge is faced with the detection of tumour-derived nucleic acid signatures.

Over the last decade, biomedical applications of nanoparticles (NPs) have been challenged due to the spontaneous adsorption of biomolecules onto their surface upon incubation with complex biofluids, known as the ‘protein’ or ‘biomolecule corona’.¹ The bio-nanotechnology field has since invested considerable resources investigating the corona composition in an attempt to prevent NP-protein interactions and consequently limit opsonisation-mediated clearance from blood and masking of surface ligands.^2-6 Protein corona formation is now a widely accepted phenomenon and has been documented for a wide range of NPs, including lipid-, metal-, polymer- and carbon-based nanomaterials, with their composition and surface chemistry altering the specific classes of proteins adsorbed.⁶

Biomolecule corona formation has become a popular line of research the last decade and ongoing research is mainly focused on the proteomic analysis of corona profiles after the ex vivo and more recently the in vivo interaction of NPs with biofluids (mainly plasma). Our laboratory has illustrated the potential exploitation of protein corona as a proteomic biomarker discovery platform that enables a higher-definition, in-depth analysis of the blood proteome and the enrichment of low abundant disease-specific molecules (see WO2018/046542 and^{8-16,13). The surface-capture of a complex blood proteome by NPs has sparked interest in utilizing the biomolecule corona fingerprinting as a proteomic discovery platform. Nanoparticle-protein interactions at the bio-nano interface not only can shed new light on the development of nanotechnologies but are now gradually being exploited as an engineering tool with therapeutic and diagnostic capabilities.}

Research into cell free nucleic acid biomarker detection has been carried out but so far has failed to provide suitable methods to accurately identify/discover and detect biomarkers. One particular problem is that currently available laboratory tests detect only a minute fraction of potential biomarkers, due to their extremely low concentration in biofluids. In addition to the ‘swamping’ effect, caused by other “non-specific” high abundant molecules, this causes significant difficulties. Furthermore, such methods are mainly used to detect already known disease-specific nucleic acid molecules (such as activating mutations associated with cancer).

Despite recent advances in analyzing the blood-circulating genome, very little attention has been placed on the utilization of the spontaneous interaction of NPs with nucleic acids upon incubation with biological fluids.

Surprisingly, the inventors have found that the biomolecule corona formed on nanoparticles after following methods involving administration of nanoparticles to a subject in a diseased state or incubation of nanoparticles in a biofluid sample taken from a subject in a diseased state results in interaction of the nanoparticles with cell free nucleic acid biomolecules as well as lipid and protein biomarkers.

The novel methods take advantage of the interaction of nanoparticles with distinct classes of biomolecules (e.g. protein, lipid, nucleic acid) which can then be analyzed simultaneously (including in parallel) as a way to detect and monitor disease and also to facilitate the detection of previously unknown disease-specific biomolecules.

SUMMARY OF THE INVENTION

The present study includes experimental evidence that cfNA exists in the biomolecule corona formed around NPs in human plasma, and at quantifiable levels. The ability of NPs to form coronas that include nucleic acid as well as other classes of biomolecule, such as lipids, metabolites and proteins and to detect/analyze these simultaneously as part of a multi-omic analysis is new.

According to a first aspect of the invention there is provided a method of identifying biomarkers from two or more distinct biomolecule classes in a biofluid, wherein the method comprises:

• • (a) contacting a plurality of nanoparticles with a biofluid to allow a biomolecule corona to form on the surface of said nanoparticles;
  • (b) isolating the nanoparticles and surface-bound biomolecule corona; and
  • (c) analyzing the biomolecule corona to identify biomarkers from two or more distinct biomarker classes.

In particular embodiments, step (a) is performed in vivo by administering a plurality of nanoparticles to a subject, such as by intravenous injection, or step (a) is performed in vitro (e.g. ex vivo) using a biofluid sample that has been taken from the subject.

Suitably the biomolecule corona is analyzed by two or more of proteomic, genomic and lipidomic analysis. Suitably, the analysis by two or more of proteomic, genomic and lipidomic analysis is conducted on a single biofluid sample. Suitably the analysis of each biomolecule class is conducted simultaneously or separately.

The method of the first aspect of the invention may be used to identify new biomarkers.

The methods result in an interaction between the nanoparticles and a greater number of different types of biomolecules, in particular proteins, than can be detected by direct analysis of biofluids taken from a subject, such as one in a diseased state. It is to be understood that the method involves identification of a biomarker that provides a measurable indicator of some biological state or condition. This includes, but is not limited to, the discovery of unique disease-specific biomolecules (those biomolecules that are only present in a diseased state) but also includes detection of changes (for example, a statistically significant change) in biomolecule(s) that are present in both healthy and diseased states, for example upregulation or down regulation of biomolecules in a diseased state when compared to the healthy state or at a different time point. It will be understood that in order to identify a potential disease-specific biomarker, comparison against a suitable non-diseased control reference can be required.

By up-regulation or down-regulation of a particular biomolecule we mean an increase or decrease, respectively, in the amount and/or abundance of the biomarker.

In particular embodiments, the biomolecule level is reduced or down-regulated to less than 90%, such as less than 80% such as less than 70% for example less than 60%, for example less than 50%, such as less than 40%, such as less than 30% such as less than 20% for example less than 10%, for example less than 5%, such as completely inhibited (0%) compared to the control level.

In particular embodiments, the biomolecule level is increased or up-regulated to more than 110%, such as more than 120% such as more than 130% for example more than 150%, for example more than 175%, such as more than 200%, such as more than 250% such as more than 300% for example more than 350% of the control amount.

In one particular embodiment, the methods involve identifying panels of biomarkers (multiplexing), which can lead to increased sensitivity and specificity of detection.

In a further particular embodiment, the methods facilitate the detection of previously unknown unique disease-specific biomolecules. In a particular embodiment, the unknown biomarkers are unique biomolecules, meaning that the biomolecules that would not have been detected if analysis was carried out directly on biofluid, such as plasma, isolated from the subject.

In yet a further particular embodiment, the methods allow identification or detection of a biomarker without the need for invasive tissue sampling, e.g. a biopsy.

The methods are applicable to a wide range of nanoparticles and allow the benefit of removal of unbound and highly abundant biomolecules to allow identification of low abundant biomarkers, in particular proteins, that would otherwise be undetected. In addition to identification of potential biomarkers, the methods can also be employed to monitor changes in biomarkers, for example in response to therapy and/or to assist in diagnosis.

Suitably, the method can be used to detect or monitor a disease in a subject. The methods disclosed herein are applicable to any disease state in which detection and/or monitoring of biomarkers would be beneficial. Furthermore, particular methods of the invention, which can be employed to distinguish between healthy and diseased states in a subject, are applicable to a wide range of diseases, including but not limited to, cancer and neurodegenerative diseases. In particular, the methods of the invention can be used to diagnose a disease, such as cancer, including in the early detection of a diseased state such as the presence of a cancer or pre-cancerous condition in a human subject. The methods of the invention can also be employed to discover novel biomarkers and biomarker fingerprints.

According to a second aspect of the invention there is provided a method for detecting a disease state in a subject, comprising:

(a) contacting a biofluid sample from the subject with a plurality of nanoparticles under conditions to allow a biomolecule corona to form on the surface of said nanoparticles; and

(b) analyzing the biomolecule corona for one or more disease-specific biomarkers from two or more biomolecule classes, which is determinative of the presence of a disease in said subject.

In a particular embodiment, the disease is cancer.

The method can be used to monitor disease progression, for example to monitor the efficacy of a therapeutic intervention. Suitably the disease is cancer. Suitable cancers include ovarian, lung, prostate, melanoma and blood cancer, including leukemia, lymphoma and myeloma. In a particular embodiment, the cancer is ovarian cancer.

According to a third aspect of the invention there is provided a method for monitoring cancer progression in a subject, comprising:

(a) contacting a biofluid sample from the subject with a plurality of nanoparticles under conditions to allow a biomolecule corona to form on the surface of said nanoparticles; and

(b) analyzing the biomolecule corona for one or more cancer-specific biomarkers from two or more biomolecule classes;

wherein the degree of cancer progression is determined based on the level of the cancer-specific biomarker(s) relative to a reference amount.

Suitably, in any of the aspects of the invention, the biofluid is blood, plasma, urine, saliva, lacrimal, cerebrospinal and ocular fluids, or any combination thereof. Suitably, the biofluid is a blood or blood fraction sample, such as serum or plasma. Suitably, the blood or blood fraction sample is from circulating blood.

In particular embodiments of any of the aspects of the invention, the biomolecule corona is analyzed by two or more of proteomic, genomic and lipidomic analysis.

The methods of any of the aspects of the invention may offer high sensitivity and a high level of precision which allows for the identification, detection and/or quantification of disease biomarkers and/or the abundance thereof, even when present in low abundance, which otherwise may be very difficult to identify.

Any embodiment described herein can be applied to any aspect of the invention unless indicated otherwise or it is apparent to the person of skill in the art that such embodiment cannot apply.

Accession numbers herein detailed are based on the SwissProt_2016_04 database.

DESCRIPTION OF THE DRAWINGS

In order that the invention may be more clearly understood one or more embodiments thereof will now be described, by way of example only, in relation to an experimental study and with reference to the accompanying drawings, of which:

FIG. 1—Schematic representation of sample pre-processing and cfDNA quantification method pipelines. A) Schematic overview of human plasma and liposomal nanoparticle (NP) incubation and subsequent size-exclusion purification methodology. B) Method analysis pipeline for plasma processing (including cfDNA purification) and subsequent q-PCR quantification of cfDNA in NP corona samples and plasma control samples.

FIG. 2—Characterisation of cfDNA content in the healthy ex vivo biomolecule corona. A) cfDNA and liposomal lipid quantification across 15 chromatographic fractions. The purified cfDNA from a single healthy pooled plasma sample incubated with and without liposomal nanoparticles (NPs) was quantified by a highly-sensitive LINE-1 real-time PCR assay. NPs and cfDNA are expressed as percentage (%) of total recovered across chromatographic fractions. B) RNase P real-time cfDNA quantification of pooled ex vivo NP⁽⁺⁾ corona samples and NP⁽⁻⁾ controls (size-purified plasma). cfDNA was measured directly and in samples with additional cfDNA purification step. C) cfDNA concentrations in NP⁽⁺⁾ corona samples and NP⁽⁻⁾ controls were confirmed using the LINE-1 real-time PCR assay. For graphs B and C cfDNA is expressed as percentage recovery (%) relative to QIAGEN's QIAamp® Circulating Nucleic Acid extraction kit (average of three replicates). All error bars represent mean and standard deviation. Groups were compared using a student t-test (p values <0.05 were considered significant).

FIG. 3—Assessing the accuracy of direct real-time PCR cfDNA quantification in ex vivo healthy and disease nanoparticle corona samples. A) RNase P real-time qPCR quantification of in pooled healthy liposomal corona samples and liposome⁽⁻⁾ plasma controls. B) Direct RNase P qPCR inhibition determined using 2-fold dilution of pooled NP corona samples. C-D) LINE-1 real-time qPCR quantification of cfDNA in late-stage serous ovarian cancer ex vivo biomolecule corona samples (n=8). Graph C represents cfDNA in NP corona samples and NP corona purified cfDNA, whereas graph D represents cfDNA in unpurified plasma (diluted 1:40) and purified plasma. All error bars represent mean and standard deviation. Groups were compared using a student t-test was performed (adjusted p values <0.05 were considered significant). E) Clinical details of eight late-stage ovarian cancer plasma samples included in graphs C and D.

FIG. 4—Reproducibility & linearity experiments of healthy plasma NP corona samples. A) Reproducibility data showing the percentage recovery (%) of QIAamp® purified NP corona cfDNA across liposome NP batches relative to QIAamp extracted plasma cfDNA (100%). B-C) Linearity data to investigate the effect of liposome concentration and plasma volume on cfDNA content in the liposome biomolecule corona. B) Graph highlighting the effect of plasma volume on cfDNA concentration (ng cfDNA/sample). Standard protocol 820 μL plasma: 180 μL liposomes. C) Graph showing the effect of liposome concentration on cfDNA concentration (ng cfDNA/sample). 12.5 mM liposomes represent standard protocol. All error bars represent mean and standard deviation. Three groups or more were compared using a one-way analyzes of variance (ANOVA) test followed by the Tukey's multiple comparison test. Adjusted p values <0.05 were considered significant.

FIG. 5—Cell-free DNA (cfDNA) detection in the ex vivo ovarian cancer biomolecule corona. A) Normalised cfDNA concentration (ng/μM lipid) in corona-coated liposomes (ovarian cancer samples and age- and sex-matched healthy controls), measured using a highly-sensitive LINE-1 real-time PCR assay and robust inhibitor-resistant polyermase. B) The same data with ovarian cancer patients separated into early stage (1 & 2) and late-stage (3 & 4) cancers. All error bars represent mean and standard deviation. Three groups or more were compared using a one-way analyzes of variance (ANOVA) test followed by the Tukey's multiple comparison test. For comparisons of two groups a student t-test was performed (adjusted p values <0.05 were considered significant).

FIG. 6—Histone proteins identified by LC-MS/MS in the biomolecule corona of healthy and ovarian cancer female plasma samples. A) LC-MS/MS normalised protein abundance of histones H2A, H2B and H4 in ovarian cancer corona samples and age-matched healthy corona controls. A one-way ANOVA was performed by the Progensis QI software with significance bars representing FDR-adjusted p values. B) Table summarising the relative abundance of proteins identified by LC-MS/MS associated with nucleosomes (DNA-histone complex) known to contain cfDNA. Max fold change between ovarian cancer corona samples and healthy corona controls is provided with FDR-adjusted p value from a one-way ANOVA in Progensis QI).

FIG. 7—Physiochemical characterisation of liposome nanoparticles (NPs). A) Graphs representing the size (diameter in nm) and zeta-potential distribution (mV) of PEG:HSPC:CHOL liposome batches 1-3. B) Table listing the mean average size (nm), polydispersity index (PDI) and zeta-potential (mV) of each liposome batch including standard deviations.

FIG. 8— Characterisation of protein, cfDNA and lipid content of the biomolecule corona. A) Schematic overview of biofluid nanoparticle incubation and size-based purification methodology. B) Negative TEM staining imaging of purified plasma controls and corona-coated nanoparticles, recovered post-incubation with human plasma obtained from healthy donors. All scale bars are 100 nm. C) Method analysis pipeline for plasma processing and subsequent quantification of proteins, nucleic acids and lipids in nanoparticle corona samples and plasma control samples.

FIG. 9— Proteomic Analysis of the nanoparticle biomolecule corona. (A) Imperial stained SDS-PAGE gels of i) purified human plasma controls and ii) corona proteins associated with liposomes post-incubation with plasma obtained from healthy donors after a two-step purification protocol; (B) Comparison between the total amount of protein i) identified in purified human plasma controls (n=3) and ii) adsorbed onto liposomes after their ex vivo incubation with plasma obtained from healthy donors (n=3) after a two-step purification protocol, (expressed as μg/mL). Protein concentration values represent the average and standard error. * indicates p<0.05 (p=0.0175); (C) Top 20 most abundant proteins found onto the surface of nanoparticles, as these identified by LC-MS/MS; (D) Classification of all identified proteins according to their molecular weight (kDa).

FIG. 10— Characterisation of cfDNA content in the iomolecule corona. A) cfDNA and liposomal lipid quantification across 15 chromatographic fractions. The purified cfDNA from healthy pooled plasma incubated with and without liposomal nanoparticles (NPs) was quantified by a sensitive LINE-1 qPCR assay. Nanoparticles and cfDNA are expressed as percentage (%) of total recovered across chromatographic fractions. B) RNase P qPCR cfDNA quantification in pooled ex vivo NP corona samples and NP⁽⁻⁾ controls (size-purified plasma). cfDNA was measured directly and in samples with additional cfDNA purification step. C) Subsequent cfDNA quantification using a sensitive LINE-1 qPCR with inhibitor resistant polymerase. cfDNA in graphs B and C is expressed as percentage recovery (%) relative to a standard total circulating nucleic acid extraction kit (Qiagen). All error bars represent mean and standard deviation. Three groups or more were compared using a one-way analyses of variance (ANOVA) test followed by the Tukey's multiple comparison test. For comparisons of two groups a student t-test was performed (adjusted p values <0.05 were considered significant).

FIG. 11—Lipidomic Analysis of the nanoparticle-biomolecule corona. (A) Quantification of complex lipids found in i) bare HSPC:CHOL liposomes and ii) corona-coated liposomes, expressed in ng per 30 μL of extracted sample. Complex lipids identified include DG: Diacylglycerols; TG: Triacylglycerols; FFA: Free Fatty Acids; PC: Phosphatidylcholines; LPC: Lysophosphatidylcholines; PE: Phosphatidylethanolamines; SM: Sphingomyelins; (B) Quantification of ceramides and endocannabinoids found in i) bare HSPC:CHOL liposomes and ii) corona-coated liposomes, expressed in ng per 50 μL of extracted sample; (C) Quantification of oxylipins found in i) bare HSPC:CHOL liposomes and ii) corona-coated liposomes, expressed in ng per 1 mL of extracted sample.

FIG. 12—Multi-omics analysis of the biomolecule corona for biomarker discovery. Proteomic and genomic comparison of the biomolecule coronas formed in plasma samples obtained from ovarian carcinoma patients and healthy controls. Volcano plots represent the potential protein biomarkers differentially abundant between: A) healthy controls and early stage ovarian cancer patients; B) healthy controls and late stage ovarian cancer patients and C) early stage and late stage ovarian cancer patients. D) Total cfDNA quantification (LINE-1 qPCR cfDNA (ng/μM lipid)) in corona-coated liposomes (ovarian cancer samples and age- and sex-matched healthy controls). Groups were compared using a one-way analyses of variance (ANOVA) test followed by the Tukey's multiple comparison test (adjusted p values <0.05 were considered significant). E) Quantitative PCR (qPCR) detection of miR-200 family microRNAs (miRNAs) in the ex vivo late-stage serous ovarian cancer corona. Graphs represent miRNA-200c and miR-141 qPCR expression, with individual patient samples connected to observe patient-specific enrichment patterns. All error bars represent mean and standard deviation. Three groups or more were compared using a one-way analyses of variance (ANOVA) test followed by the Tukey's multiple comparison test. Adjusted p values <0.05 were considered significant.

DETAILED DESCRIPTION OF THE INVENTION

The practice of particular embodiments of the invention will employ, unless indicated specifically to the contrary, conventional methods of chemistry, biochemistry, organic chemistry, molecular biology, microbiology, recombinant DNA techniques, genetics, immunology, and cell biology that are within the skill of the art, many of which are described below for the purpose of illustration. Such techniques are explained fully in the literature. See, e.g., Sambrook, et al., Molecular Cloning: A Laboratory Manual (3rd Edition, 2001); Ausubel et al., Current Protocols in Molecular Biology (John Wiley and Sons, updated July 2008); Short Protocols in Molecular Biology: A Compendium of Methods from Current Protocols in Molecular Biology, Greene Pub. Associates and Wiley-Interscience.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by those of ordinary skill in the art to which the invention belongs. Although any methods and materials similar or equivalent to those described herein can be used in the practice or testing of the present invention, preferred embodiments of compositions, methods and materials are described herein.

Definitions

The articles “a,” “an,” and “the” are used herein to refer to one or to more than one (i.e. to at least one) of the grammatical object of the article.

The use of the alternative (e.g., “or”) should be understood to mean either one, both, or any combination thereof of the alternatives.

The term “and/or” should be understood to mean either one, or both of the alternatives.

As used herein, the term “about” or “approximately” refers to a quantity, level, value, number, frequency, percentage, dimension, size, amount, weight or length that varies by as much as 15%, 10%, 9%, 8%, 7%, 6%, 5%, 4%, 3%, 2% or 1% to a reference quantity, level, value, number, frequency, percentage, dimension, size, amount, weight or length. In one embodiment, the term “about” or “approximately” refers a range of quantity, level, value, number, frequency, percentage, dimension, size, amount, weight or length ±15%, ±10%, ±9%, ±8%, ±7%, ±6%, ±5%, ±4%, ±3%, ±2%, or ±1% about a reference quantity, level, value, number, frequency, percentage, dimension, size, amount, weight or length.

The term “biomolecule” includes, but is not limited to, proteins, peptides, fatty acids, lipids, amino acids, amides, sugars and nucleic acids (such as for example different types of DNA or RNA).

As used herein, the term “disease-specific biomarker” refers to a biomarker which is associated with or indicative of a disease. Examples of certain cancer-specific biomarkers include: mutations in genes of KRAS, p53, EGFR or erbB2 for colorectal, esophageal, liver, and pancreatic cancer; mutations in BRCA1 and BRCA2 genes for breast and ovarian cancer; and, abnormal methylation of tumor suppressor genes p16, CDKN2B, and p14ARF for brain cancer. As used herein, the term “high-throughput sequencing” is also referred to as “second-generation sequencing,” and the principles of high-throughput sequencing techniques are well known to those of skill in the art, and high-throughput sequencing is typically performed on microporous chips. High throughput sequencing techniques and the reagents and devices used therein are conventional in the art. Commercially available high throughput sequencing chips and reagents are readily available, for example, from Life Technologies Inc. To conduct high throughput sequencing the cfDNA captured in the corona may need a pre-treatment process such as amplification, end-repair, ligation, labeling and/or purification, etc. in order to construct a cfDNA library prior to high-throughput sequencing, and the techniques required for this are understood by those of skill in the art of high-throughput sequencing, and can be constructed, for example, using the NEBNext Fast DNA Fragmentation & Library Prep Set for Ion Torrent (Life Technologies Cat. No. 4474180) kit.

As used herein, the term “in vitro” means performed or taking place in a test tube, culture dish, or elsewhere outside a living organism. The term also includes ex vivo because the analysis takes place outside an organism.

As used herein, the term “isolated” means material that is substantially or essentially free from components that normally accompany it in its native state. In particular embodiments, the term “obtained” or “derived” is used synonymously with isolated.

Multi-omics is a biological analysis approach in which the data sets are multiple “omes”, such as the genome, proteome, transcriptome, epigenome, lipidome and metabolome. For a review on multi-omics see Hasin et al. Genome Biology. “Multi-omics approaches to disease”. 18(83), 2017; https://doi.org/10.1186/s13059-017-1215-1.

As used herein “multi-omics” means analysis that generates data at two or more biological levels including at the genome, epigenome, transcriptome, proteome, and metabolome level. As used herein, “multi-omic analysis” refers to two or more types of analysis selected from: nucleic acid, protein and lipid analysis.

Genomics is an area within genetics that concerns the sequencing and analysis of an organism's genome. The genome is the entire DNA content that is present within one cell of an organism.

As used herein, “genomics” is the analysis of genes and nucleic acids generally (including DNA and RNA), and includes transcriptomics (the study of RNA generally and in particular RNA transcripts).

As used herein, “proteomics” is the analysis of proteins and elements of protein (referred to herein as a protein element or protein derivative) such as peptides (short chains of amino acids, e.g. 2-10 amino acids) and polypeptides (longer chains of amino acids).

Lipidomics is the large-scale study of pathways and networks of cellular lipids in a biological system. The term “lipidome” is often used to describe the complete lipid profile within a cell, tissue, organism, or ecosystem and is a subset of the term “metabolome” which also includes the three other major classes of biological molecules: proteins/amino-acids, sugars and nucleic acids.

As used herein, “lipidomics” is the analysis of lipids and elements of lipids. The metabolome is typically defined as the complete complement of all small molecule metabolites (<1500 Da), such as metabolic intermediates, hormones and other signaling molecules, and secondary metabolites, found in a specific cell, organ or organism (Wishart DS Human metabolome database: completing the ‘human parts list’. Pharmacogenomics 8:683-686, 2007). Metabolomics is the scientific study of chemical processes involving metabolites, the small molecule substrates, intermediates and products of metabolism.

A “target genetic locus” or “nucleic acid target region” refers to a region of interest within a nucleic acid sequence. In various embodiments, targeted genetic analyzes are performed on the target genetic locus. In particular embodiments, the nucleic acid target region is a region of a gene that is associated with a particular genetic state, genetic condition, genetic diseases; genetic mosaicism, predicting response to drug treatment; diagnosing or monitoring a medical condition; microbiome profiling; pathogen screening; or organ transplant monitoring.

As used herein “targeted genetic analyzes” refers to investigations of specific known genetic regions, including mutations, for example those that are known to be associated with a disease. Exemplary genetic regions include genes (e.g. any region of DNA encoding a functional product) or a part thereof, gene products (e.g., RNA and expression of genes). The genetic regions can include variations with the sequence or copy number. Exemplary variations include, but are not limited to, a single nucleotide polymorphism, a deletion, an insertion, an inversion, a genetic rearrangement, a copy number variation, or a combination thereof. The methods of the invention can be used to isolate cfNA that can then be subjected to any desired targeted genetic analysis.

As used herein, the terms “circulating NA,” “circulating cell-free NA” and “cell-free NA” are often used interchangeably and refer to nucleic acid that is extracellular DNA or RNA, DNA or RNA that has been extruded from cells, or DNA or RNA that has been released from lysed, necrotic or apoptotic cells.

A “subject,” “individual,” or “patient” as used herein, includes any animal that exhibits a symptom of a condition that can be detected or identified with compositions contemplated herein. Suitable subjects include laboratory animals (such as mouse, rat, rabbit, or guinea pig), farm animals (such as horses, cows, sheep, pigs), and domestic animals or pets (such as a cat or dog). In particular embodiments, the subject is a mammal. In certain embodiments, the subject is a non-human primate and, in a particular embodiment, the subject is a human.

A major limitation of classical omic studies is the analysis at only one level of biological complexity. For example, transcriptomic studies will provide information at the transcript level, but many different entities contribute to the biological state of the sample (genomic variants, post-translational modifications, lipid products, metabolic products, interacting organisms, among others). With the advent of high-throughput biology, it is becoming increasingly affordable to make multiple measurements, allowing transdomain (e.g. RNA and protein levels) correlations and inferences. These correlations aid the construction or more complete biological networks, filling gaps in our knowledge.

It is therefore desirable to identify platforms systems that facilitate multi-omic analysis.

Methods of the Invention

According to a first aspect of the invention there is provided a method of identifying biomarkers from two or more distinct biomolecule classes in a biofluid, wherein the method comprises:

• • (a) contacting a plurality of nanoparticles with a biofluid to allow a biomolecule corona to form on the surface of said nanoparticles;
  • (b) isolating the nanoparticles and surface-bound biomolecule corona; and
  • (c) analyzing the biomolecule corona to identify biomarkers from two or more distinct biomarker classes.

Advantageously, the method according to the first aspect is used to identify biomarkers from two or more distinct biomolecule classes. It is to be understood that the term “identify” in this context relates to discovering biomarkers which are new (i.e., previously not known and/or previously not associated with a particular disease or stage of disease that the subject from which the biofluid was taken has).

In one embodiment, there is provided the method according to the first aspect wherein the method identifies biomarkers from two or more distinct biomolecule classes in a biofluid from a subject in a diseased state wherein the biomarkers have previously not associated with a particular disease or stage of disease.

In one embodiment of the first aspect of the invention, there is provided a method of identifying biomarkers from two or more distinct biomolecule classes in a biofluid, wherein the method comprises:

• • (a) contacting a plurality of nanoparticles with a biofluid to allow a biomolecule corona to form on the surface of said nanoparticles;
  • (b) isolating the nanoparticles and surface-bound biomolecule corona; and
  • (c) analyzing the biomolecule corona to identify biomarkers from two or more distinct biomarker classes wherein the biomolecule corona is analyzed by two or more of proteomic, genomic and lipidomic analysis.

In particular embodiments, step (a) is performed in vivo by administering a plurality of nanoparticles to a subject or in vitro/ex vivo using a biofluid sample that has been taken from the subject.

In a particular embodiment, step (a) is performed in vivo by administering a plurality of nanoparticles to a subject, a biofluid sample is then taken from the subject and analyzed. Prior to analysis, the particles are isolated from the biofluid and purified to remove unbound and highly abundant biomolecules. In one embodiment the nanoparticles are administered to the subject by intravenous injection.

According to a variation of the first aspect of the invention there is provided a method of identifying biomarkers from two or more distinct biomolecule classes in a biofluid, wherein the method comprises:

• • (a) administering a plurality of nanoparticles to a subject to allow a biomolecule corona to form on the surface of said nanoparticles;
  • (b) isolating the nanoparticles and surface-bound biomolecule corona; and
  • (c) analyzing the biomolecule corona to identify biomarkers from two or more distinct biomarker classes.

In this approach, step (a) of the method involves administering a plurality of nanoparticles to a subject to allow a biomolecule corona to form on the surface of said nanoparticles. Suitably, administration can be by any route that allows the biomolecule corona to form. Suitable routes of administration include but are not limited to intravenous, oral, intracerebral (including spinal), intraperitoneal and intra-occular. Conveniently, the route of administration is by intravenous injection. The biomolecule corona typically forms within less than 10 minutes from administration. Suitably, the subject is suffering from a disease (is in a diseased state).

A biofluid sample comprising some of the introduced nanoparticles is then extracted from the subject; for example, by taking a blood sample. In a particular embodiment, the nanoparticles are isolated from the biofluid sample prior to analysis. Any isolation technique that is capable of preserving the surface-bound biomolecule corona is suitable. Conveniently, the nanoparticles with surface-bound biomolecule corona are isolated from the biofluid and purified to remove unbound and highly abundant biomolecules (for example albumin and/or immunoglobulins, which can constitute 90% of the plasma proteome) to allow identification of lower abundant biomarkers. The method therefore allows minimization of any masking caused by the highly abundant proteins. Conveniently, the isolation is achieved by a method comprising size exclusion chromatography followed by ultrafiltration.

According to another variation of the first aspect of the invention there is provided a method of identifying biomarkers from two or more distinct biomolecule classes in a biofluid, wherein the method comprises:

• • (a) incubating a plurality of nanoparticles in a biofluid sample taken from a subject to allow a biomolecule corona to form on the surface of said nanoparticles.
  • (b) isolating the nanoparticles and surface-bound biomolecule corona; and
  • (c) analyzing the biomolecule corona to identify biomarkers from two or more distinct biomarker classes.

In particular embodiments of this aspect of the invention, in step (c) at least one of the biomarker classes is selected from the group consisting of: protein, nucleic acid and lipid, or any complexes of these (such as nucleic acid/protein complex).

Suitably, such incubation can be carried out ex vivo or in vitro (herein the term in vitro includes ex vivo). In this approach, the NP corona is formed in vitro by incubating the plurality of nanoparticles in a biofluid sample to be analyzed. Conveniently, this involves incubating at a suitable temperature, such as at about 37° C., for a suitable length of time. The biomolecule corona can form almost immediately, but typically the incubation is carried out for a period of 5-60 minutes, or more; such as 5, 10, 15, 20, 30, 40, 50, 60 or more minutes. Conveniently, the mixture can be subject to agitation, for example by way of an orbital shaker set at approximately 250 rpm to mimic in vivo conditions. Suitably, the biofluid sample from the subject to be analyzed has been previously taken and the sample extraction step is not part of the method.

Thus, according to a particular embodiment, the plurality of nanoparticles are incubated in the test biofluid sample ex vivo/in vitro under conditions to allow a biomolecule corona to form on the surface of said nanoparticles.

In accordance with the first aspect of the invention, the corona may be digested prior to step (c) in order to facilitate analysis.

In one embodiment, the subject is suffering from a disease and optionally, after step (c) the abundance of the one or more biomarkers is compared to the abundance of the one or more biomarkers in a non-diseased control reference.

In embodiments where the non-diseased control reference comprises a biomolecule corona obtained from a healthy subject, said corona may be digested prior to the equivalent steps of its own analysis.

In some embodiments, albumin and/or immunoglobins may not be depleted from corona samples (which may include for example a corona from a healthy subject) prior to analysis.

The methods of the first aspect of the invention may also be useful for monitoring changes in the amount of the biomarkers, for example in response to therapy. Therefore, in some embodiments, the method may comprise an extra step, during or (preferably before step (a) of administering a therapy to the subject, for example administering a drug molecule, such as for example, an anti-cancer compound. Suitable anti-cancer compounds include, but are not limited to, compounds with activity in cancers such as lung cancer, melanoma or ovarian cancer. In some embodiments, the anti-cancer compound is doxorubicin.

The results obtained in step (c) can be compared to a non-diseased control reference which may comprise the results of corona analysis obtained from a healthy subject. The corona obtained from a healthy subject may be obtained by the same or similar method steps as steps (a) and (b) of the method and may be analyzed by the same or similar method step as step (c) of the method. The healthy subject may be a subject who does not have the type of disease (e.g. cancer) for which the likelihood thereof is being assessed, who does not have any form of disease and/or who does not have any serious illnesses or diseases (e.g. a subject who is generally considered, for example by doctors or other medical practitioners, to be healthy and/or substantially free from disease or illness or serious disease or illness).

A further step (d) may comprise determination and/or calculation of relative or differential abundance between the corona and the non-diseased control reference (such as analysis results of a corona obtained by the same or similar method steps as steps (a) to (c) of the method, but wherein the subject is a healthy subject from a healthy subject) with respect to the or each of the one or more biomarkers. Step (c) and/or (d) may comprise the use of a computer program or software tool. Step (c) and/or (d) may comprise analysis (such as computer or software analysis) of raw data obtained from analyses and/or measurements, for example raw data obtained from LC/MS of the or each corona. Step (c) and/or (d) may comprise a statistical comparison between the protein abundance of the one or more protein biomarkers in the corona and in the non-diseased control reference.

The corona may be digested prior to step (c) and/or step (d), in order to facilitate analysis. In embodiments where the non-diseased control reference comprises a protein corona obtained from a healthy subject, said corona may be digested prior to the equivalent steps of its own analysis.

In particular embodiments of any aspect of the invention, the biomolecule corona is subjected to proteomic analysis, such as via LC-MS/MS or a bicinchoninic acid assay (BCA assay), such as further described herein.

In particular embodiments of any aspect of the invention, the biomolecule corona is subjected to lipidic analysis, such as via UPLC/ESI-MS/MS

In particular embodiments of any aspect of the invention, the biomolecule corona is subjected to genomic analysis, such as via LC-MS/MS or sequence analysis, such as further described herein. Stroun et al. (Neoplastic characteristics of the DNA found in the plasma of cancer patients. Oncology. 46 (5): 318-322, 1989) described that certain characteristics of tumour DNA could be found in a patient's cfDNA. Subsequent publications have confirmed that tumour cells can release their DNA into the circulation. In 1996 Chen et al. (Nat. Med 2:1033-1035, 1996) and Nawroz et al. (Nat. Med 2:1035-1037, 1996) reported the presence of tumour-associated microsatellite alterations, such as loss of heterozygosity (LOH) and microsatellite shifts, in serum and plasma of cancer patients. Circulating free DNA is therefore a useful source material for cancer diagnosis and monitoring.

The inventors have found that analysis of the liposome corona formed in plasma samples obtained from ovarian carcinoma patients revealed higher total cfDNA content compared to healthy controls, suggesting a disease-specific biomolecule corona.

Thus, according to particular embodiments, the method can be used to diagnose or monitor a disease, such as cancer. Suitable cancers include ovarian, lung, prostate, melanoma and blood cancer, including leukemia, lymphoma and myeloma.

The method may be useful in the early detection of a diseased state such as the presence of a tumour in a human subject or for monitoring disease progression and/or response to treatment without the need for invasive tissue sampling, e.g. a biopsy.

According to a second aspect of the invention there is provided a method for detecting a disease state in a subject, comprising:

(a) contacting a biofluid sample from the subject with a plurality of nanoparticles under conditions to allow a biomolecule corona to form on the surface of said nanoparticles; and

(b) analyzing the biomolecule corona for one or more disease-specific biomarkers from two or more biomolecule classes, which is determinative of the presence of a disease in said subject.

In one embodiment, there is provided a method for detecting a disease state in a subject, comprising:

(a) contacting a biofluid sample from the subject with a plurality of nanoparticles under conditions to allow a biomolecule corona to form on the surface of said nanoparticles; and

(b) analyzing the biomolecule corona for one or more disease-specific biomarkers from two or more biomolecule classes, which is determinative of the presence of a disease in said subject wherein the biomolecule corona is analyzed by two or more of proteomic, genomic and lipidomic analysis.

In a particular embodiment, the disease state is cancer. In particular embodiments, the cancer is selected from the group consisting of: lung, ovarian, prostate, melanoma and blood cancer, including leukemia, lymphoma and myeloma.

The method can be used to monitor disease progression, for example to monitor the efficacy of a therapeutic intervention. Suitably the disease is cancer. In a particular embodiment, the cancer is ovarian cancer. Suitably the method involved detecting one or more tumour-specific biomarker over time.

Optionally, after step (a) and before step (b) the nanoparticles and surface-bound biomolecule corona are isolated.

Any isolation technique that is capable of preserving the surface-bound biomolecule corona is suitable. Conveniently, the nanoparticles with surface-bound biomolecule corona are isolated from the biofluid and purified to remove unbound and highly abundant biomolecules (for example albumin) to allow identification of lower abundant biomarkers. The method therefore allows minimization of any masking caused by the highly abundant proteins. Conveniently, the isolation is achieved by a method comprising size exclusion chromatography followed by ultrafiltration.

As with the first aspect of the invention, step (a) of this second aspect of the invention involve administering a plurality of nanoparticles to a subject to allow a biomolecule corona to form on the surface of said nanoparticles or incubating a plurality of nanoparticles in a biofluid sample taken from a subject to allow a biomolecule corona to form on the surface of said nanoparticles. Suitable routes of administration include but are not limited to intravenous, oral, intracerebral (including spinal), intraperitoneal and intra-occular. Conveniently, the route of administration is by intravenous injection. The biomolecule corona typically forms within less than 10 minutes from administration.

In a further embodiment of the second aspect, step (a) comprises incubating a plurality of nanoparticles in a biofluid sample taken from a subject to allow a biomolecule corona to form on the surface of said nanoparticles. Suitably, such incubation can be carried out ex vivo or in vitro (herein the term in vitro includes ex vivo). In this approach, the NP corona is formed in vitro by incubating the plurality of nanoparticles in a biofluid sample to be analyzed. Conveniently, this involves incubating at a suitable temperature, such as at about 37° C., for a suitable length of time. The biomolecule corona can form almost immediately, but typically the incubation is carried out for a period of 5-60 minutes, or more; such as 5, 10, 15, 20, 30, 40, 50, 60 or more minutes. Conveniently, the mixture can be subject to agitation, for example by way of an orbital shaker set at approximately 250 rpm to mimic in vivo conditions. Suitably, the biofluid sample from the subject to be analyzed has been previously taken and the sample extraction step is not part of the method.

In one embodiment of any aspect of the invention, when the corona is subjected to nucleic acid analysis (e.g. genomics), the NA level is determined based on quantifying at least one cancer-associated mutation. Suitably, the quantification of the NA level is done at different time points so as to monitor disease progression. In one embodiment of any aspect of the invention, the nucleic acid being detected in cell-free nucleic acid, such as cfDNA or cfRNA. In another embodiment of any aspect of the invention, when the corona is subjected to protein analysis (e.g. proteomics), a protein, polypeptide or protein possessing, or indicative of a disease-associated mutation is detected. In another embodiment of any aspect of the invention, the biomolecule corona is analyzed at the nucleic acid and protein level. In another embodiment of any aspect of the invention, the biomolecule corona is analyzed at the nucleic acid and lipid level. In another embodiment of any aspect of the invention, the biomolecule corona is analyzed at the protein and lipid level. In another embodiment of any aspect of in the invention, the biomolecule corona is analyzed at the protein, lipid and nucleic acid level.

According to a third aspect of the invention there is provided a method for monitoring disease progression in a subject, comprising:

(a) contacting a biofluid sample from the subject with a plurality of nanoparticles under conditions to allow a biomolecule corona to form on the surface of said nanoparticles; and

(b) analyzing the biomolecule corona for one or more disease-specific biomarkers from two or more biomolecule classes; wherein the degree of cancer progression is determined based on the level of the disease-specific biomarker(s) relative to a reference amount.

In one embodiment, there is provided a method for monitoring disease progression in a subject, comprising:

(a) contacting a biofluid sample from the subject with a plurality of nanoparticles under conditions to allow a biomolecule corona to form on the surface of said nanoparticles; and

(b) analyzing the biomolecule corona for one or more disease-specific biomarkers from two or more biomolecule classes;

wherein the degree of cancer progression is determined based on the level of the disease-specific biomarker(s) relative to a reference amount

wherein the biomolecule corona is analyzed by two or more of proteomic, genomic and lipidomic analysis.

As with the first and second aspects of the invention, step (a) of this third aspect of the invention may involve administering a plurality of nanoparticles to a subject to allow a biomolecule corona to form on the surface of said nanoparticles or incubating a plurality of nanoparticles in a biofluid sample taken from a subject to allow a biomolecule corona to form on the surface of said nanoparticles. Suitable routes of administration include but are not limited to intravenous, oral, intracerebral (including spinal), intraperitoneal and intra-occular. Conveniently, the route of administration is by intravenous injection. The biomolecule corona typically forms within less than 10 minutes from administration.

In an alternative embodiment, step (a) comprises incubating a plurality of nanoparticles in a biofluid sample taken from a subject to allow a biomolecule corona to form on the surface of said nanoparticles. Suitably, such incubation can be carried out ex vivo or in vitro (herein the term in vitro includes ex vivo). In this approach, the NP corona is formed in vitro by incubating the plurality of nanoparticles in a biofluid sample to be analyzed. Conveniently, this involves incubating at a suitable temperature, such as at about 37° C., for a suitable length of time. The biomolecule corona can form almost immediately, but typically the incubation is carried out for a period of 5-60 minutes, or more; such as 5, 10, 15, 20, 30, 40, 50, 60 or more minutes. Conveniently, the mixture can be subject to agitation, for example by way of an orbital shaker set at approximately 250 rpm to mimic in vivo conditions. Suitably, the biofluid sample from the subject to be analyzed has been previously taken and the sample extraction step is not part of the method.

Optionally, after step (a) and before step (b) the nanoparticles and surface-bound biomolecule corona are isolated.

In a particular embodiment, the disease is cancer. In particular embodiments, the cancer is selected from the group consisting of: lung, ovarian, prostate, melanoma and blood cancer, including leukemia, lymphoma and myeloma.

In a particular embodiment, the reference amount is the amount detected at a previous time point, for example, at least 1 week, 2 weeks, 1 month, 3 months, 6 months, 12 months, 18 months, or 24 months earlier.

In a particular embodiment, if the total amount of the biomarker being measured (analyzed) has increased compared to the reference amount it signifies that the patient's disease has progressed and if the total amount of the biomarker has decreased compared to the reference amount the patient's disease has regressed.

Any isolation technique that is capable of preserving the surface-bound biomolecule corona is suitable. Conveniently, the nanoparticles with surface-bound biomolecule corona are isolated from the biofluid and purified to remove unbound and highly abundant biomolecules (for example albumin) to allow identification of lower abundant biomarkers. The method therefore allows minimization of any masking caused by the highly abundant proteins. Conveniently, the isolation is achieved by a method comprising size exclusion chromatography followed by ultrafiltration.

In a particular embodiment of any of the aspect of the invention, the nanoparticles with surface-bound biomolecule corona are isolated from the biofluid and purified to remove unbound and highly abundant biomolecules to allow identification of low abundant biomarkers.

In a particular embodiment of any of the aspect of the invention, the nanoparticles with surface-bound biomolecule corona are isolated from the biofluid and purified by a method comprising size exclusion chromatography followed by ultrafiltration.

The method of the second and third aspects of the invention may offer high sensitivity and a high level of precision which allows for the identification, detection and/or quantification of the disease markers, e.g. cancer biomarkers and/or the abundance thereof, even when present in low abundance, which otherwise may be very difficult to identify.

In particular embodiments, the disease is cancer selected from the group consisting of: lung, ovarian, prostate, melanoma and blood cancer, including leukemia, lymphoma and myeloma.

In a particular embodiment of any aspect of the invention, the method may further comprise a step of determining the abundance (such as normalised abundance, mean normalised abundance, % abundance, for example) of the or each analyzed biomarker in the corona.

When the biofluid sample is from a subject with or suspected of having a disease the abundance of one or more biomarkers in the corona can be compared to the abundance of the same one or more biomarkers in a non-diseased control reference.

In particular embodiments of any aspect of the invention, at least one of the biomarker(s) is a complex between nucleic acid and a protein or protein derivative.

In particular embodiments of any aspect of the invention, the method may comprise determining the abundance of at least 1, 2, 3, 5, 10, 20, 30, 40, 50, 75, 100, 150, 200, 250, 300 or at least 350 biomarkers, and optionally, comparing the results with the abundance of the same biomarkers in a non-diseased control reference.

In a particular embodiment of any aspect of the present invention, the analysis is conducted on a single biofluid sample. Suitably, the sample is a plasma sample.

In a particular embodiment, the invention relates to a method of identifying a new biomarker from a biofluid, wherein the method comprises:

• • (a) isolating a plurality of nanoparticles with surface-bound biomolecule corona from a biofluid sample taken from a subject in a diseased state; and
  • (b) analyzing the biomolecule corona to identify biomarkers from two or more distinct biomarker classes;
  • (c) identifying one or more new biomarkers.

Surprisingly, inventors have found that the total cfDNA biomolecule content of the biomolecule corona isolated after administering a plurality of nanoparticles to ovarian cancer subjects to allow a biomolecule corona to form on the surface of the nanoparticles is significantly higher in comparison to healthy subjects. FIG. 5 shows data to illustrate this surprising discovery. When normalised to post-purification liposome concentration, cfDNA was significantly higher in ovarian cancer samples (all stages, early stage (I and II) and late-stage (III and IV)) compared to healthy controls (p values=<0.001, <0.01 and <0.0001, respectively). Similar findings were found with total protein levels.

The protein and/or cfNA content adsorbed onto the nanoparticle can therefore be used to detect or diagnose the disease state. Protein and/or cfNA detection in the NP corona can therefore be used to indicate the presence of disease in a subject.

Proteomic Analysis

The various aspects of the invention are directed to the detection/identification of one or more biomarkers. In a particular embodiment of any aspect of the invention, at least one of the biomarker(s) is a protein or protein derivative.

In a particular embodiment of any aspect of the present invention, at least one of the biomolecule classes analyzed is protein and the protein or protein derivative is analyzed directly without prior extraction or purification from the NP corona.

Analysis of the biomolecule corona in order to identify proteinaceous biomarkers can be carried out using any suitable technique capable of detecting said biomarkers.

The total protein biomolecule content of the biomolecule corona can be determined by any method capable of quantifying the level of said biomolecules in the surface-bound corona. In one embodiment, the total protein content is determined by bicinchoninic acid (BCA) assay. In one particular embodiment, the subject is a human patient and the total protein content is at least 700, 800, 900, 1000, 1250, 1500, 1800, 2000, 25000 or 3000 Pb when measured using a BCA assay.

In addition to a determination of the total biomolecule content of the biomolecule corona, analysis of the biomolecule corona can also reveal qualitative and quantitative information regarding specific potential biomarkers. Such analysis can be carried out using any suitable techniques of capable of detecting said biomarkers. Protein mass spectrometry is often used for the accurate mass determination and characterization of molecules, including proteins, and a variety of methods and instrumentations have been developed for its many uses.

In a particular embodiment of the invention, the biomolecule corona is analyzed by gel electrophoresis, mass spectrometry, an immunoassay, UV-Vis. absorption, fluorescence spectroscopy, chromatography or NMR methodology. Conveniently, the biomolecule corona is analysed by mass spectrometry, which can allow qualitative and quantitative analysis of the biomolecule corona present on the nanoparticles. In a particular embodiment, the methods allow identification of unique biomolecules without the need for highly specialized and ultra-sensitive analytical mass spectrometry instrumentation such as using an UltiMate® 3000 Rapid Separation LC (RSLC, Dionex Corporation, Sunnyvale, Calif.) coupled to a LTQ Velos Pro (Thermo Fisher Scientific, Waltham, Mass.) mass spectrometer.

In one aspect of this embodiment, analysis of the biomolecule corona is carried out after administering a plurality of nanoparticles to a subject in a diseased state to allow a biomolecule corona to form on the surface of said nanoparticles and isolating the nanoparticles and surface-bound biomolecule corona. When compared to other methods, such methods can yield high levels of unique low abundant biomolecules and allow identification of such unique biomolecules without the need for highly specialized and ultra-sensitive analytical mass spectrometry instrumentation such as an UltiMate® 3000 Rapid Separation LC (RSLC, Dionex Corporation, Sunnyvale, Calif.) coupled to a LTQ Velos Pro (Thermo Fisher Scientific, Waltham, Mass.) mass spectrometer.

In a particular embodiment of the invention, the beneficial sensitivity and high level of precision provided by the method allows the identification of intracellular protein disease related biomarkers that are present in low abundance and would otherwise be very difficult to identify. Conveniently, the method allows identification of protein biomarkers with molecular weight of less than 80 kDa. More conveniently, the method allows identification of protein biomarkers with molecular weight of less than 40 kDa or less than 20 kDa.

Surprisingly, inventors have also found that the total protein content determined by administering a plurality of nanoparticles to a subject is greater than if determined by incubating the plurality of nanoparticles in-vitro with a biofluid taken from the subject. In a particular embodiment, the total protein content determined is at least between 1.2 and 5 fold higher than if determined by incubating the plurality of nanoparticles in-vitro with a biofluid isolated from the subject. Conveniently, total protein content determined is at least 1.5, 1.8, 2, 3, 4 or 5 fold higher than if determined by incubating the plurality of nanoparticles in-vitro with a biofluid isolated from the subject. Conveniently, the subject in this embodiment is a human.

Genomic/Nucleic Acid Analysis

The various aspects of the invention are directed to the detection/identification of one or more biomarkers. In a particular embodiment of any aspect of the invention, at least one of the biomarker(s) is nucleic acid. Suitably, the biomarker is a nucleic acid target region. In a particular embodiment of any aspect of the invention, at least one of the biomarker(s) is cell-free nucleic acid (cfNA). Suitably, in any of the aspects of the invention, the cfNA is cell free ribonucleic acid (cfRNA) or cell free deoxyribonucleic acid (cfDNA). cfRNA can be any cell-free RNA including microRNA. cfDNA can be any cell free DNA, including genomic DNA. Suitably, the cfNA is fragmented. In a particular embodiment, the cfNA is nucleic acid released from a cancer cell. Such nucleic acid may comprise or house one or more mutations associated with the cancer.

The nucleic acid (such as cell free nucleic acid) that forms or adsorbs onto the nanoparticles (either directly or indirectly by association with another biomolecules, such as a protein) can be subjected to genetic analysis by any technique of interest. Such analysis could be quantitating total nucleic acid, sequencing of the nucleic acid and/or undertaking one or more targeted genetic analyzes using known molecular diagnostic techniques to test the genetic state of an individual, including assessing for genetic diseases; mendelian disorders; genetic mosaicism; predicting response to drug treatment; and/or diagnosing or monitoring a medical condition. In addition, the nucleic acid-based cancer diagnostics contemplated herein possess the ability to detect a variety of genetic changes including somatic sequence variations that alter protein function, large-scale chromosomal rearrangements that create chimeric gene fusions, and copy number variation that includes loss or gain of gene copies.

When analysing nucleic acid, it may be preferably to fragment the target nucleic acid. Nucleic acids, including genomic nucleic acids, can be fragmented using any of a variety of methods, such as mechanical fragmenting, chemical fragmenting, and enzymatic fragmenting. Methods of nucleic acid fragmentation are known in the art and include, but are not limited to, DNase digestion, sonication, mechanical shearing, and the like.

Genomic nucleic acids can be fragmented into uniform fragments or randomly fragmented. In certain aspects, nucleic acids are fragmented to form fragments having a fragment length and/or ranges of fragment lengths as required depending on the type of nucleic acid targets one seeks to capture and the design and type of probes such as molecular inversion probes (MIPs) that will be used. Chemical fragmentation of genomic nucleic acids can be achieved using methods such as a hydrolysis reaction or by altering temperature or pH. Nucleic acid may be fragmented by heating a nucleic acid immersed in a buffer system at a certain temperature for a certain period to time to initiate hydrolysis and thus fragment the nucleic acid. The pH of the buffer system, duration of heating, and temperature can be varied to achieve a desired fragmentation of the nucleic acid. Mechanical shearing of nucleic acids into fragments can be used e.g., by hydro-shearing, trituration through a needle, and sonication. Nucleic acid may also be fragmented enzymatically. Enzymatic fragmenting, also known as enzymatic cleavage, cuts nucleic acids into fragments using enzymes, such as endonucleases, exonucleases, ribozymes, and DNAzymes. Varying enzymatic fragmenting techniques are well-known in the art.

In certain embodiments, the sample nucleic acid is captured or targeted using any suitable capture method or assay such as amplification with PCR, hybridization capture, or capture by probes such as MIPs.

In a particular embodiment of any aspect of the present invention, the nucleic acid in the NP corona is isolated and fragmented before analysis.

In a particular embodiment of any aspect of the invention, the nucleic acid content of the biomolecule corona is quantitated using qPCR, such as real time qPCR. In one embodiment, the nucleic acid is cfNA, such as cfDNA.

Prior to the analysis of the nucleic acid in the surface-bound biomolecule corona it may be desirable to amplify the nucleic acid using the well-established technique of polymerase chain reaction (PCR). Alternatively, a nucleic acid library of the nucleic acid in the surface-bound biomolecule corona could be generated.

A suitable DNA library could be generated by the end-repair of isolated DNA, wherein fragmented DNA (e.g. cfDNA) is processed by end-repair enzymes to generate end-repaired DNA with blunt ends, 5′-overhangs, or 3′-overhangs which can then be cloned into a suitable vector, e.g. plasmid, and used to generate a DNA clone library. Optionally, an adaptor is ligated to each end of an end-repaired DNA, and each adaptor comprises one or more PCR or sequencing primer binding sites. If desired, PCR can then amplify the initial DNA library. The amount of amplified product can be measured using methods known in the art, e.g., quantification on a Qubit 2.0 or Nanodrop instrument.

In particular embodiments, a method for genetic analysis of DNA comprises: generating and amplifying a DNA library, determining the number of genome equivalents in the DNA library; and performing a quantitative genetic analysis of one or more target loci.

In particular embodiments, a method for genetic analysis of DNA comprises treating DNA with one or more end-repair enzymes to generate end-repaired DNA and ligating one or more adaptors to each end of the end-repaired DNA to generate a DNA library; amplifying the DNA library to generate DNA library clones; determining the number of genome equivalents of DNA library clones; and performing a quantitative genetic analysis of one or more target genetic loci in the DNA library clones.

The nucleic acid captured in the corona can be subjected to nucleotide sequencing by any method known in the art. DNA sequencing techniques include classic dideoxy sequencing reactions (Sanger method) using labelled terminators or primers and gel separation in slab or capillary, sequencing by synthesis using reversibly terminated labelled nucleotides or using allele specific hybridization to a library of labelled clones, Illumina/Solexa sequencing, pyrosequencing, 454 sequencing, and SOLiD sequencing. Separated molecules may be sequenced by sequential or single extension reactions using polymerases or ligases as well as by single or sequential differential hybridizations with libraries of probes.

An example of a suitable sequencing technique is Illumina sequencing which is based on the amplification of DNA on a solid surface using fold-back PCR and anchored primers. Genomic DNA is fragmented, and adapters are added to the 5′ and 3′ ends of the fragments. DNA fragments that are attached to the surface of flow cell channels are extended and bridge amplified. The fragments become double stranded, and the double stranded molecules are denatured. Multiple cycles of the solid-phase amplification followed by denaturation can create several million clusters of approximately 1,000 copies of single-stranded DNA molecules of the same template in each channel of the flow cell. Primers, DNA polymerase and four fluorophore-labelled, reversibly terminating nucleotides are used to perform sequential sequencing. After nucleotide incorporation, a laser is used to excite the fluorophores, and an image is captured and the identity of the first base is recorded. The 3′ terminators and fluorophores from each incorporated base are removed and the incorporation, detection and identification steps are repeated. Sequencing according to this technology is described in various patent publications including: U.S. Pat. Nos. 7,960,120; 7,835,871; 7,232,656 and 6,210,891.

With the advances in next generation sequencing, the cost of sequencing whole genomes has decreased dramatically, however the cost and time involved in sequencing entire genomes may not be practical or necessary. Instead, different genome partitioning techniques can be used to isolate smaller but highly specific regions of the genome for further analysis. Molecular Inversion Probe (MIP) technology, for instance, can be used to capture a small region of the genome for further examination, such as single nucleotide polymorphism (SNP) genotyping, allelic imbalance studies or copy number variation assessments (e.g. Hardenbol et al., “Highly multiplexed molecular inversion probe genotyping: over 10,000 targeted SNPs genotyped in a single tube assay”. Genome Res 15:269-75, 2005).

In a particular embodiment of any aspect of the present invention, at least one of the biomolecule classes analyzed is nucleic acid and the amount or relative amount of total cfNA is determined.

In a particular embodiment of any aspect of the present invention, at least one of the biomolecule classes analyzed is nucleic acid and the amount or relative amount of total cfDNA is determined.

In a particular embodiment of any aspect of the present invention, the amount of at least one biomarker in the corona is quantitated directly without prior extraction or purification.

In a particular embodiment of any aspect of the present invention, at least one of the biomolecule classes analyzed is nucleic acid and the nucleic acid is analyzed directly without prior extraction or purification from the NP corona.

In a particular embodiment of any aspect of the present invention, at least one of the biomolecule classes analyzed is cfDNA and the cfDNA is analyzed directly without prior extraction or purification from the NP corona.

In a particular embodiment of any aspect of the present invention, a specific nucleic acid sequence within the biofluid is detected. Suitably, the specific nucleic acid is indicative of a disease, such as being or comprising a disease-associated mutation. One example is the detection of activating mutations in epidermal growth factor receptor (EGFR) gene in certain patients with non-small cell lung cancer (NSCLC). Key activating mutations in EGFR include: a deletion in exon 19 (e.g. Del (746-750)) and the L858R point mutation that constitute approximately 90% of all EGFR activating mutations in NSCLC patients. The methods of the invention can be used to detect one or more EGFR activating mutations, or indeed, resistance mutations, and so can be used for diagnosis or monitoring purposes.

The present invention includes methods for identifying a cell free nucleic acid biomarker in a biofluid.

In a particular embodiment of any aspect of the invention the cfNA is adsorbed onto the surface of a nanoparticle. Suitably, the cfNA is adsorbed onto the nanoparticle surface as part of a Nucleic Acid-protein complex. In particular embodiments, the Nucleic Acid-protein complex comprises one or more histone proteins, such as H2, H2B, H4, histone-lysine N-methyltransferase 2D and histone PARylation factor 1. In particular embodiments, the Nucleic Acid-protein complex is a DNA-protein complex.

The total biomolecule content of the cfNA biomolecule corona can be determined by any method capable of quantifying the level of said biomolecules in the surface-bound corona. In one embodiment, the biomolecule method involves determining the total nucleic acid content and this is suitably determined by qPCR. Total NA content can be gauged by measuring a reference gene, such as the RNase P gene (e.g. using The Applied Biosystems® TaqMan™ RNase P Detection Reagents Kit).

In one embodiment, the cfNA is detected directly from the NP corona. In another embodiment, the cfNA is purified from the corona before analysis. Purification of nucleic acid is well-known. A suitable kit for purifying circulating nucleic acid in a sample is QIAamp circulating nucleic acid extraction kit (QIAGEN).

Unique cfNA biomarkers can also be detected by nucleic acid sequencing, either direct on the corona or following polymerase chain reaction amplification of cfNA in the corona.

In a particular embodiment of the invention, the beneficial sensitivity and high level of precision provided by the method allows the identification of intracellular cfNA disease related biomarkers that are present in low abundance and would otherwise be very difficult to identify.

Lipid Analysis.

The various aspects of the invention are directed to the detection/identification of one or more biomarkers. In a particular embodiment of any aspect of the invention, at least one of the biomarker(s) is a lipid.

Lipids are typically analysed by chromatographic methods. The most common chromatographic methods for lipid analysis are thin-layer chromatography (TLC), GC, and high-performance liquid chromatography (HPLC), used alone or in conjugation with mass spectrometry (MS), tandem quadrupoles (MS/MS), flame ionization detector (FID), and time-of-flight (TOF). In a particular embodiment, the analysis is ultra-performance liquid chromatography-electrospray ionization-tandem mass spectrometry (UPLC-ESI-MS/MS).

In a particular embodiment of any aspect of the present invention, at least one of the biomolecule classes analyzed is lipid and the lipid is analyzed directly without prior extraction or purification from the NP corona.

Metabolomics

Metabolomic analyses typically utilize nuclear magnetic resonance (NMR)-based detection, or gas or liquid chromatography coupled to mass spectrometry (MS), e.g. LC-MS and LC-MS/MS, which typically allows the detection of 3000-5000 molecules per experiment. MS-based approaches outperform NMR in terms of sensitivity and can be run in an untargeted or targeted approach. A commercial or in-house targeted approach set up might interrogate between 10 and several hundred metabolites per run.

Biofluid

The biofluid can be any fluid obtained or obtainable from a subject. The subject can be an animal. In a particular embodiment of any aspect of the invention the subject is a human. In particular embodiments, the subject is suffering from a disease (in a diseased state).

In particular embodiments of any aspect of the invention, the biofluid is selected from blood, plasma, serum, saliva, sputum, urine, ascites, lacrimal, cerebrospinal and ocular fluids. In a particular embodiment, the biofluid is plasma.

Suitably the biofluid is a blood or blood fraction sample, such as serum or plasma.

In a particular embodiment, the biofluid has been produced from a solid tissue, such as a solid tumor tissue, by treatment to macerate/lyse the tissue to generate a fluid.

Nanoparticles

A plurality of nanoparticles can be a population of the same type of nanoparticle (a population of nanoparticles) or more than one population of nanoparticles, wherein each population is of a different type of nanoparticle; and so when combined can be termed a heterogeneous population of nanoparticles (i.e. a plurality of distinct nanoparticle populations).

Certain classes of nanoparticle are more effective at adsorbing different biomolecules, therefore by utilizing a mixture of distinct nanoparticles (i.e. two or more distinct nanoparticle populations) it will be possible to create a corona that comprises a particular complement of biomolecules and/or as many biomolecule species as possible.

Thus, in a particular embodiment the plurality of nanoparticles used is a heterogeneous population of nanoparticles.

In a particular embodiment, all the nanoparticles used in the method are of the same type of nanoparticle, and so can be termed a homogeneous population of nanoparticles.

In one embodiment, there is provided a method of identifying biomarkers from two or more distinct biomolecule classes in a biofluid, wherein the method comprises:

• • (a) contacting a plurality of nanoparticles with a biofluid to allow a biomolecule corona to form on the surface of said nanoparticles;
  • (b) isolating the nanoparticles and surface-bound biomolecule corona; and
  • (c) analyzing the biomolecule corona to identify biomarkers from two or more distinct biomarker classes;

wherein the plurality of nanoparticles is a homogeneous population of nanoparticles.

In one embodiment, there is provided a method for detecting a disease state in a subject, comprising:

• • (a) contacting a biofluid sample from the subject with a plurality of nanoparticles under conditions to allow a biomolecule corona to form on the surface of said nanoparticles; and
  • (b) analyzing the biomolecule corona for one or more disease-specific biomarkers from two or more biomolecule classes, which is determinative of the presence of a disease in said subject;

wherein the plurality of nanoparticles is a homogeneous population of nanoparticles.

In one embodiment, there is provided a method for monitoring cancer progression in a subject, comprising:

• • (a) contacting a biofluid sample from the subject with a plurality of nanoparticles under conditions to allow a biomolecule corona to form on the surface of said nanoparticles; and
  • (b) analyzing the biomolecule corona for one or more cancer-specific biomarkers from two or more biomolecule classes;

wherein the degree of cancer progression is determined based on the level of the cancer-specific biomarker(s) relative to a reference amount; and

wherein the plurality of nanoparticles is a homogeneous population of nanoparticles.

The methods are applicable to any types of nanoparticles capable of attracting a biomolecule corona. In a particular embodiment of any aspect of the invention, the nanoparticles are selected from liposomes, metallic nanoparticles (such as gold or silver nanoparticles), polymeric nanoparticles, fibre shaped nanoparticles (such as carbon nanotubes) and 2-dimensional nanoparticles (such as graphene oxide nanoparticles) or any combination thereof. In a particular embodiment, the nanoparticles are PEGylated liposomes.

Suitably, the nanoparticles comprise liposomes. Conveniently, the nanoparticles are liposomes. Liposomes are generally spherical vesicles comprising at least one lipid bilayer. Liposomes are often composed of phospholipids. In a particular embodiment, the liposomes are composed of phospholipid molecules and functionalised amphiphilic molecules (eg. PEGylated DSPE). In a particular embodiment, the liposomes are composed of phospholipid molecules and functionalised amphiphilic molecules (eg. PEGylated DSPE) that are able to self-assemble into unilamellar vesicles. In a particular embodiment, the liposomes are PEGylated DSPE. Conveniently, the liposomes are able to encapsulate drug molecules in their inner aqueous phase, and in some embodiments may contain one or more drug molecules therein. In one embodiment, the drug molecule is doxorubicin, or a pharmaceutically acceptable salt thereof. In one embodiment, the drug molecule is doxorubicin hydrochloride.

The inventors have found that NA-containing coronas form on negatively charged nanoparticles. As nucleic acid is negatively charged this is surprising. In a particular embodiment, the nanoparticles are negatively charged.

Biomolecule Corona

The corona formed on the nanoparticles is a biomolecule corona. Conveniently, the biomolecule corona will typically comprise different classes of biomolecule, such as proteins, peptides, fatty acids, lipids, amino acids, amides, sugars and nucleic acids. Conveniently the biomolecule corona comprises proteins and/or lipids and/or nucleic acid, such as cell free nucleic acid (e.g. cfDNA and/or cfRNA). Conveniently the biomolecule corona comprises one or more measurable biomarkers.

As mentioned elsewhere herein, the biomolecule corona can form almost immediately, but typically the incubation is carried out for a period of 5-60 minutes, or more; such as 5, 10, 15, 20, 30, 40, 50, 60 or more minutes. Conveniently, the mixture can be subject to agitation, for example by way of an orbital shaker set at approximately 250 rpm to mimic in vivo conditions. Suitably, the biofluid sample from the subject to be analyzed has been previously taken and the sample extraction step is not part of the method.

In the methods of the invention that involve administration of the nanoparticles to a subject, a biofluid sample comprising some of the introduced nanoparticles is then extracted from the subject; for example, by taking a blood sample, after a period of time to allow the corona to form. In particular embodiments, the biofluid sample comprising nanoparticles is extracted/removed from the subject at least 5 minutes after administration, such as at least 5, 6, 7, 8, 9, 10, 12, 15, 20, 30, 40, 60, 90, 120 minutes or more, after the nanoparticles were administered to the subject. The volume of the biofluid sample comprising nanoparticles extracted can be determined by the physician and will depend on the source of the biofluid sample. For example, if it is a blood sample, it may be in a volume of 2-20 ml. In a particular embodiment, the nanoparticles are isolated from the biofluid sample prior to analysis.

In particular embodiments, the methods of the invention comprise administering a plurality of nanoparticles to a subject, a biofluid sample is then taken from the subject and analysed. Prior to analysis, the particles are isolated from the biofluid and purified to remove unbound and highly abundant biomolecules. In one embodiment the plurality of nanoparticles are administered to the subject by intravenous injection.

Multi-Omic Analysis

Once the biomolecule corona has been formed the sample can be split into portions and each portion subjected to a particular-omic analysis as describe herein. In certain circumstances, it may be possible to simultaneously analyze one sample by more than one-omic analysis. Thus, the analysis from two or more distinct biomarker classes can be done on the same sample containing the nanoparticle-biomolecule corona, or it can be carried out separately on distinct portions of the original sample.

A biomarker, or biological marker, generally refers to a qualitative and/or quantitative measurable indicator of some biological state or condition. Biomarkers are typically molecules, biological species or biological events that can be used for the detection, diagnosis, prognosis and prediction of therapeutic response of diseases. Most biomarker research has been focused on measuring a concentration change in a known/suspected biomarker in a biological sample associated with a disease. Such biomarkers can exist at extremely low concentrations, for example in early stage cancer, and accurate determination of such low concentration biomarkers has remained a significant challenge.

In a particular embodiment of any aspect of the present invention, the relative amount of a biomarker in the sample is determined by reference to a control amount in the sample. A control nucleic acid may be a nucleic acid sequence, such as a gene, that is representative of a wild-type/healthy level. A control protein may be a protein that is representative of a wild-type/healthy level. A control lipid may be a lipid that is representative of a wild-type/healthy level.

In particular embodiments of any aspect of the invention, the method may comprise determining the abundance of at least 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 15, 20, 25, 30, 35, 40, 45, 50, 75, 100, 150, 200 or at least 250 biomarkers, and optionally, comparing the results with the abundance of the same biomarkers in a non-diseased control reference.

Monitoring effects of therapy The methods of the invention can be used to monitor the effects of a therapeutic treatment. For example, a determination of one or more biomarkers in a patient's biofluid can be conducted prior to a therapeutic intervention (such as chemotherapy, radiotherapy or administration of any therapeutic drug) and then at one or more time points during or after treatment. A change in the amount of the biomarker(s) detected can then be used to determine the effectiveness of the treatment.

Therefore, in some embodiments, the method may comprise an extra step, during or (preferably before step (a)), of administering a therapy to the subject, for example administering a drug molecule, such as for example, an anti-cancer compound. Suitable anti-cancer compounds include, but are not limited to, compounds with activity in cancers such as lung cancer, melanoma or ovarian cancer. In some embodiments, the anti-cancer compound is doxorubicin.

In a separate embodiment, there is provided a method for monitoring the changes in biomarkers in a subject in response to therapy, comprising the step of (a) contacting a plurality of nanoparticles with a biofluid from a therapeutically treated subject with cancer to allow a biomolecule corona to form on the surface of said nanoparticles.

In a particular embodiment of any aspect of the present invention, at least one of the biomolecule classes analyzed is nucleic acid and a change in total cfNA in a biofluid from a subject in response to therapy is monitored. In a particular embodiment of any aspect of the present invention, a change in cfNA of a cancer-associated genetic marker (e.g. mutation) in a biofluid from a subject in response to therapy is monitored.

In a particular embodiment of any aspect of the present invention, at least one of the biomolecule classes analyzed is protein and a change in total protein content in a biofluid from a subject in response to therapy is monitored.

In a particular embodiment of any aspect of the present invention, at least one of the biomolecule classes analyzed is lipid and a change in total lipid content in a biofluid from a subject in response to therapy is monitored.

In a particular embodiment, the therapy comprises administration of a drug molecule to the subject.

In a particular embodiment, the patient is being treated with an anti-cancer compound. Conveniently, the anti-cancer compound is doxorubicin.

Panels of Biomarkers

In addition to the identification of a single biomarker, the methods of the invention also provide the ability to identify panels of biomarkers (multiplexing). This approach can lead to increased sensitivity and specificity of detection. In a particular embodiment of any aspect of the invention, the biomarker is part of a panel of disease-specific biomolecule biomarkers. In a further embodiment, the panel comprises a combination of unknown and known disease-specific biomolecule biomarkers.

Kits

In a further aspect of the invention, there is provided a diagnostic kit comprising nanoparticles and reagents capable of detecting one or more of the biomolecules listed in Table 2, Table 3, Table 4, Table 5, Table 6, Table 7 or Table 8.

Use of Protein Biomarkers

In a further aspect of the invention, there is provided any one or more of the biomolecules listed in Table 2, Table 3, Table 4, Table 5, Table 6, Table 7 or Table 8, or any combinations thereof, for use as a biomarker.

EXAMPLES

Materials and Methods

M1. Plasma samples. Healthy human female pooled K2EDTA plasma samples were purchased from BiolVT (West Sussex, UK) (Lot #HMN2528). All ovarian cancer K2EDTA plasma samples were collected by the MCRC Biobank (details provided in Table 1 and FIG. 3E). Individual age- and sex-matched K2EDTA plasma controls (female, 45-85 years old) were purchased from BiolVT (West Sussex, UK) (Table 1). All plasma samples were stored at −80° C.

M2. Liposome preparation. HSPC:Chol:DSPE-PEG2000 (56.3:38.2:5.5) liposomes (Doxil® formulation) liposomes were prepared using the thin lipid film method followed by extrusion as described previously.¹⁴ All liposome batches were diluted to 12.5 mM, with the same batch of liposomes used for group comparisons. The physiochemical characteristics of the liposome batches are shown in FIG. 7.

M3. Dynamic light scattering (DLS) for size and zeta-potential measurements. Liposome size and surface charge were measured as described previously.¹⁴ Liposomes were diluted in distilled water and measured in size or capillary cuvettes using the Zetasizer Nano ZS (Malvern, Instruments, UK).

M4. Biomolecule corona formation (liposome plasma incubation and purification). Liposome and plasma incubations and purifications were performed as described previously.¹⁴ In brief, 820 μL human plasma and 180 μL PEGylated liposomes were incubated for 10 mins at 37° C., shaking at 250 rpm. Unbound proteins and other unknown biomolecules were removed by size exclusion chromatography (SEC) (Sepharose CL-4B columns (Sigma-Aldrich)) followed by membrane ultrafiltration (Vivaspin® columns (Sartorious, Fisher Scientific)). Samples were concentrated to 100 μL for characterisation or downstream processing. For characterisation of individual chromatographic fractions, samples were concentrated to 100 μL using 1,000,000 molecular weight cut off (MWCO) Vivaspin® membrane ultrafiltration columns ((Sartorious, Fisher Scientific). Plasma controls were subjected to the same purification process for comparison.

M5. Circulating cell-free nucleic acid extraction. Cell-free nucleic acids were purified from ex vivo plasma samples, liposomal corona samples and plasma control samples using a QIAamp® Circulating Nucleic Acid Extraction kit and QIAvac 24 Plus vacuum manifold according to manufacturer's instructions (QIAGEN, Hilden, Germany). After an initial sample lysis step, cell-free nucleic acids were bound onto a silica-based purification column (QIAGEN mini column). Multiple washing steps were performed prior to elution of cell-free nucleic acids in buffer AVE (QIAGEN). All samples were eluted in a final volume of 50 μL.

M6. Cell-free DNA quantification. Cell-free DNA was measured using two real-time quantitative PCR (qPCR) assays. The single-copy RNase P probe real-time assay was performed using TaqMan® RNase P Detection Reagents kit (Life Technologies) and SensiFAST Probe Hi-ROX master mix (Bioline, Meridian Bioscience). All real-time qPCR reactions included 7.5 μL of 2× SensiFAST probe mastermix, 0.75 μL 20× RNase P primer/probe mix, 1.75 μL nuclease-free water (Ambion, Tex., USA) and 5 μL of sample. Cycling conditions included (95° C., 5 mins)×1, (95° C., s; 60° C., 50 s)×40 and were performed on a LightCycler® 96 (Roche, Basel, Switzerland).

The multi-locus LINE-1 real-time qPCR assay was performed using primers described previously⁷³ purchased from Integrated DNA Technologies (desalted, 25 nmol scale) using a robust Terra qPCR Direct SYBR Premix master mix (Takara Bio, USA). All real-time PCR reactions included 7.5 μL of 2× Terra qPCR Direct SYBR Premix master mix, 0.75 μL of each 10 μM forward and reverse primers), 5.75 μL nuclease-free water (Ambion, Tex., USA) and 1 μL of sample. Cycling conditions included (98° C., 2 mins)×1, (98° C., 10 s; 60° C., 15 s; 68° C., 30 s)×35 and were performed on a LightCycler® 96 (Roche, Basel, Switzerland).

Sample input was either corona-coated liposomes, purified cfDNA or plasma samples diluted 1:40. Plasma samples were only quantified using the LINE-1 real-time PCR assay in combination with the robust Terra qPCR Direct SYBR Premix master mix.

M7. Mass spectrometry. In-gel digestion of corona proteins was performed prior to LC-MS/MS analysis, as described previously.¹⁴ Digested proteins were analyzed by LC-MS/MS using an UltiMate 3000 Rapid Separation LC (RSLC, Dionex Corporation, Sunnyvale, Calif.) plus Q Exactive Hybrid Quadrupole-Orbitrap (Thermo Fisher Scientific, Waltham, Mass., USA) mass spectrometer system. Data were analyzed using Mascot (Matrix Science UK) in combination with the SwissProt_2016_04 database (taxonomy human). Progenisis QI software (version 4.3.2, Proteome Software Inc.) was used for relative protein quantification based on spectral counting and statistical analyzes (One-way analyzes of variance (ANOVA)).

The accession numbers of the proteins indicated in Tables 2-5 were assigned using SwissProt_2016_04 database.

M8. Statistical analysis. Statistical comparisons of these data were performed using GraphPad Prism v.8.2.0. For comparisons of three groups or more, one-way ANOVA tests were performed followed by the Tukey's multiple comparison test (adjusted p values <0.05 were considered significant). For comparisons of two groups unpaired student t-tests were performed (FDR-adjusted p values <0.05 were considered significant). All data averages were presented as mean±standard deviation (SD).

M9. Ethical Approvals: This project has research ethics approval under the Manchester Cancer Research Centre (MCRC) Biobank Research Tissue Bank Ethics (NHS NW Research Ethics Committee 18/NW/0092). All participants provided written informed consent to participate in this study.

Example 1

1.1 Plasma Incubation and Biomolecule Corona Formation.

To evaluate the cfDNA content of the biomolecule corona, human plasma samples obtained from healthy volunteers were incubated (37° C., 10 minutes, 250 rpm) with PEGylated liposomes (HSPC:Chol:DSPE-PEG2000), a formulation which constitutes the basis of the anti-cancer agent Doxil®. (FIG. 7). Liposomes were employed in this study due to their extensive protein corona characterisation, their use in nucleic acid-based biotechnology applications and more recently due to their promise as a proteomic enrichment tool.^9,35,36,42

In order to assess the potential interaction of cfDNA with PEGylated liposomal surfaces, plasma-incubated liposomes were purified by size exclusion chromatography (SEC); represented in FIG. 1A), as described previously.14 Plasma control samples (without prior incubation with liposomes) were subjected to the exact same purification process. SEC column-eluted cfDNA was extracted from chromatographic fractions 1-15, using a QIAamp® circulating nucleic acid extraction kit (QIAGEN) and subsequently quantified using robust and highly sensitive LINE-1 real-time qPCR assay (FIG. 2A). Stewart assay was also performed in order to quantify the amount of liposomes eluted.

As illustrated in FIG. 2A and in agreement with our previous studies,¹⁴ corona-coated liposomes were eluted in chromatographic fractions 5 and 6, while no detectable lipid content was found in the fractionated plasma control. Distribution of cfDNA across chromatographic fractions 1-15 revealed significant differences between plasma-incubated liposomes and the matched plasma control. In the case of the plasma-incubated liposome sample the majority of cfDNA (45.8%) was eluted in chromatographic fraction 5, which also contained the largest population of liposome NPs (66.7%), while liposome-free fractions 7-15 contained relatively small quantities of cfDNA (<6%). In contrast, a normal distribution of cfDNA was evident in the fractionated plasma control, with the highest amount of cfDNA detected in fraction 10 (18.8%). Notably, in the absence of NPs, only 2.6% of the cfDNA content was detected in fraction 5. The striking difference in cfDNA distribution between corona-coated liposomes and the fractionated plasma control suggests that a significant proportion of cfDNA eluted in fraction 5 could be associated with the eluted liposomes.

Our data provide the first experimental evidence of the presence of cfDNA in the NP corona samples and show that the majority of cfDNA detected is associated with the surface of liposomes and is not passively co-eluted during purification (FIGS. 2A-C).

1.2 Quantitative Detection of cfDNA in the Liposome Corona.

To further purify corona-coated liposomes from any remaining protein complexes and/or unbound cfDNA, chromatographic fractions 5 and 6 were pooled, concentrated and subsequently washed three times using a membrane ultrafiltration column (Vivaspin®, 1 million MWCO). 8,9,11

To determine the total cfDNA content of the liposomal corona two different real-time qPCR assays were utilised, as outlined in FIG. 1B. A real-time qPCR approach was chosen as the concentration of cfDNA in blood commonly falls below the lower limit of detection for absorbance and fluorescence-based DNA quantification methods. Initially, a standardised TagMan® RNase P detection real-time qPCR assay (Applied Biosystems®) was used to quantify the cfDNA content of the biomolecule corona in healthy plasma samples. As illustrated in FIG. 2B, the concentration of cfDNA measured in the corona samples was significantly higher in comparison to plasma control samples that underwent the full purification process (adjusted p-value<0.0001). A small amount of cfDNA was identified in purified plasma controls, suggesting a co-elution of a small population of cfDNA molecules complexed with large proteins or within extracellular vesicles (FIG. 2B). These data suggested that most of the cfDNA quantified in corona samples is associated (directly or indirectly) with the surface of liposomes and was not passively co-eluted in a size-dependent manner.

In order to investigate whether the presence of proteins and/or other molecules in the biomolecule corona affects the direct quantification of cfDNA, we compared the amount of cfDNA with and without prior extraction (QIAGEN's QIAamp® circulating nucleic acid extraction kit). Comparable amounts of cfDNA were detected using the TaqMan® RNase P assay both in corona-coated liposome samples and in cfDNA subsequently purified from the same corona samples (FIG. 2B). These data indicated that the real-time qPCR assay was not significantly inhibited by other molecules present in the corona, allowing direct cfDNA measurements in the presence of lipid-based NPs and complex biofluid contaminants. To further investigate qPCR inhibition in NP-corona samples, a 2-fold dilution was performed prior to real-time qPCR quantification (FIGS. 3A&B). The cfDNA quantity of the 1:2 diluted corona sample was approximately half that of the original measurement (48%), providing further evidence to support the lack of RNase P qPCR inhibition in these direct real-time PCR measurements. The concentration of cfDNA in the NP-corona samples and plasma controls (with no NPs) was confirmed with a robust and sensitive LINE-1 qPCR assay (FIG. 2C). Both assays produced similar values, with RNase P and LINE-1 quantification methods consistently detecting significantly more cfDNA in corona samples when compared to plasma controls, as shown in FIG. 2C.

In terms of reproducibility, the percentage of cfDNA recovered with liposomal NPs was consistent across healthy plasma and liposome batches (FIG. 4A). In addition, plasma linearity experiments revealed a significant reduction in total cfDNA content when plasma input volume was lowered, while the plasma:NP ratio was maintained (adjusted p-values <0.01 for both 410 μL & 205 μL of plasma when compared to 810 μL) (FIG. 4B). In contrast to the linear relationship observed between plasma volume and cfDNA concentration, altering the concentration of liposome NPs did not significantly affect the amount cfDNA recovered (FIG. 3C). Combined, these data suggested that at the NP concentrations investigated, liposomes interacted reproducibly with a sub-population of plasma cfDNA molecules and that a NP:plasma [μL:μL] ratio of 0.2 was found optimal to recover this fraction of cfDNA.

Direct quantification of cfDNA was possible within complex lipid-based biomolecule corona samples without prior cfDNA extraction using the QIAamp circulating nucleic acid extraction kit (QIAGEN). In addition, cfDNA was successfully purified from lipid NPs using a standard cfDNA extraction kit, highlighting the compatibility of lipid-based NPs with downstream purification and quantification methods.

1.3 Detection of cfDNA in Ovarian Carcinoma Liposomal Corona Samples.

To establish whether cfDNA could also be detected on the surface of liposomes incubated ex vivo with plasma obtained from cancer patients, corona-coated liposomes were prepared upon incubation and purification from plasma samples obtained from 43 patients with ovarian cancer (18 patients with FIGO stage I, 8 with stage II, 12 with stage III and 5 with stage IV) (Table 1).

TABLE 1
Table outlining clinical characteristics of ovarian cancer patient cohort and healthy normal volunteers (HNVs). Details
include sample number (n), age-range (years), histological subtype, germline BRCA mutation status, baseline CA125
concentration (U/mL), prior lines of chemotherapy and platinum sensitivity.
	Ovarian cancer patients
	Healthy	Stage 1	Stage 2	Stage 3	Stage 4
Sample number	11	18	8	12	5
Age-range (median)	40-59 (51)	21-87	(59)	32-77	(60)	37-74	(62)	36-67	(48)
Histological subtype	N/A	Mucinous-11	(61%)	Serous-6	(75%)	Serous-9	(75%)	Serous-5	(100%)
		Serous-5	(28%)	Endometroid-2	(25%)	Adenocarcinoma	(17%)
		Clear cell-1	(5.5%)			(NOS)-2
		Endometroid-1	(5.5%)			Carcinosarcoma-1	(8%)
Germline BRCA	N/A	Positive-0	(0%)	Positive-0	(0%)	Positive-1	(8%)	Positive-1	(20%)
status		Negative-1	(5.5%)	Negative-3	(37.5%)	Negative-0	(0%)	Negative-3	(60%)
		Unknown-17	(94.5%)	Unknown-5	(62.5%)	Unknown-11	(92%)	Unknown-1	(20%)
Baseline CA125	N/A	Median 60	(12-550)	Median 29.5	(4-600)	Median 16	(7-358)	Median 15	(9-396)
(U/mL)
Prior lines of	N/A	0	(94%)	0	(62.5%)	0	(50%)	0	(20%)
chemotherapy		2	(6%)	1	(37.5%)	1	(42%)	1	(80%)
						2	(8%)
Platinum sensitivity	N/A	Sensitive-6	(33%)	Sensitive-3	(37.5%)	Sensitive-1	(8%)	Sensitive-2	(40%)
		Resistant-1	(6%)	Resistant-1	(12.5%)	Resistant-0	(0%)	Resistant-1	(20%)
		Unknown-11	(61%)	Unknown-4	(50%)	Unknown-11	(92%)	Unknown-2	(40%)

Patients with ovarian cancer classified across all stages of the disease were included in the study to determine whether cfDNA could be detected in NP corona samples both at early stages and as the disease progressed. These samples were quantified directly using a robust high sensitivity LINE-1 qPCR assay and compared to corona samples from 11 healthy aged matched females (FIG. 5). When normalised to post-purification liposome concentration, cfDNA was significantly higher in ovarian cancer samples (all stages, early stage (I and II) and late-stage (III and IV)) compared to healthy controls (p values=<0.001, <0.01 and <0.0001, respectively) (FIG. 5). In addition, average cfDNA content increased from early (FIGO stage I and II) to late stage (FIGO stage III and IV), although this was not statistically significant (FIG. 5B). These data are consistent with previous studies that have proposed quantification cfDNA as a diagnostic and prognostic biomarker for ovarian cancer, with increased cfDNA levels detected with disease progression.^43,44

To determine whether direct cfDNA quantification in ovarian cancer corona samples would be inaccurate and skewed, with real-time qPCR inhibition increasing disproportionately with cancer stage, we compared cfDNA concentration in purified and unpurified samples for eight late-stage (stage III n=6, stage IV n=2) high-grade serous ovarian cancer samples (details provided in FIG. 3E). Similar cfDNA concentrations were measured for both unpurified ovarian cancer corona samples and their respective purified cfDNA samples (FIG. 3C). This suggests that real-time qPCR was not significantly inhibited in these biomolecule corona qPCR reactions and that no significant cfDNA loss occurred during cfDNA extraction using QIAGEN's QIAamp® circulating nucleic acid extraction kit. We were also able to measure the cfDNA content directly in ovarian cancer plasma samples (diluted 1:40), which again showed no significant difference from the respective purified plasma cfDNA samples (FIG. 3D).

Mass spectrometry (LC-MS/MS) proteomic analysis was then performed on the 43 samples from ovarian cancer patients and the 11 samples from healthy controls to investigate whether proteins known to associate with cfDNA could be detected in the biomolecule corona (FIG. 6). Histone proteins, H2A, H2B and H4, which are found within the core nucleosome complex, were detected in the biomolecule corona and were identified at significantly higher levels in ovarian cancer samples relative to healthy controls (FIG. 6A). Two additional nucleosome-interacting proteins were identified in these samples, namely histone-lysine N-methyltransferase 2D and histone PARylation factor 1 (FIG. 6B)⁴⁵ Combined, these data confirmed the presence of cfDNA in the biomolecule corona of liposomes and suggested an indirect interaction which is potentially mediated via the nucleosome complex.

1.4

The PEGylated liposomes used in this study have a negative surface charge (FIG. 7A), therefore it was considered unlikely that DNA molecules would be bound directly onto the liposome surface via electrostatic interactions. Considering that cfDNA is protected within nucleosome complexes in the blood,⁴⁸ we hypothesised that cfDNA may not be directly bound onto the liposome surface, but through the adsorption of DNA-protein complexes. This indirect mechanism of adsorption was further supported by the identification of positively charged nucleosome core proteins, including histone proteins H2A, H2B and H4, in the biomolecule corona by LC-MS/MS analysis (FIG. 6). Of note, our group has previously detected histone proteins in human ex vivo, human in vivo and mouse in vivo liposomal corona samples.^8,10,13 Moreover, human histone proteins (H2B and H4) have also been identified in the healthy corona of colloidal gold NPs.⁵² Furthermore, De Paoli and colleagues demonstrated that calf thymus histone H1 binds to carboxylated-multiwalled carbon nanotubes (CNTCOOH).⁵³ In addition, consistent cfDNA recovery across batches (FIG. 4A) suggested its reproducible and stable interaction with the liposomal surface as part of the biomolecule corona.

1.5 Discussion

Our data demonstrated that the corona-containing cfDNA levels were significantly higher in the biomolecule coronas formed upon incubation with plasma samples obtained from ovarian cancer patients (both early- and late-stages) in comparison to healthy controls (FIG. 5). It has been widely reported that total cfDNA is elevated in many different cancer types, such as colorectal, glioblastoma, colorectal and breast cancer, and increases with progression of the disease.^44,54-57 It is important to clarify that DNA originating from the tumour frequently only makes up a small proportion of total cfDNA, with the majority of DNA molecules released from non-malignant cells.^48,58 Moreover, healthy cfDNA detected in individuals with cancer is commonly of hematopoietic origin and can be attributed to increased white blood cell turnover and chemotherapeutic- and/or radiation-induced cell death.^48,54 The elevated cfDNA detected in ovarian cancer patients in this study may therefore be attributable to cfDNA released from normal cells.

The ability to conduct genomic analysis on NP-corona offers up the ability to discover and analyze cancer-specific biomarkers in the NP corona. This approach could offer significant advantages over current purification methods, which lack the sensitivity required to detect ctDNA in small volumes of human plasma in patients with low tumour burden, especially pertinent to the challenge of early cancer detection.

Previous observations have shown that physiological diseased states affects blood composition, which is reflected in corona formation.⁸ For example, our group has previously shown that protein corona quantitatively and qualitatively changed in the presence of tumorigenesis, with higher total amount of protein found to interact with intravenously injected liposomes recovered from melanoma and lung adenocarcinoma tumour-bearing mice in comparison to healthy controls.⁸ Further analysis revealed that histone H2A was significantly upregulated in the in vivo lung adenocarcinoma corona samples.⁸ Therefore, the increased amount of nucleosome-related proteins in ovarian cancer samples is likely to extend to other cancer types and NP classes, as a general reflection of increased cfDNA and histone content, commonly seen in cancer.^47,59-81 In terms of other pathological conditions, our previous analysis of the ex vivo corona formed in the plasma of sepsis patients revealed a significant increase in histone H2B compared to plasma from both systemic inflammatory response syndrome (SIRS) patients and healthy controls.¹⁰ Comprehensive comparison of ‘healthy’ and ‘diseased’ protein coronas has been found to be a very promising enrichment tool for plasma analysis, enabling proteomic discovery of low abundant, diagnostic biomarkers.^9,10

In recent years, other cell-free nucleic acids, such as miRNAs, have received growing interest as disease biomarkers⁶² and although extensive characterisation of the NP corona nucleic acid content was beyond the scope of this study, it remains an important avenue of future research. In addition, epigenetic analysis of ctDNA, such as differential methylation profiles can also provide cancer-specific signatures.⁶³ Intriguingly, methyl-cytosines have been shown to display a strong affinity to bare metal surfaces, including gold nanoparticles.^64,65 Furthermore, post translational modifications of histone proteins have also been widely associated with tumourigenesis and have been previously detected in the plasma of cancer patients.^68-71 The molecular complexes of cell-free nucleic acids contained with the biomolecule corona need to be fully elucidated in order to establish the scope for a sensitive blood-based biomarker enrichment tool.

The molecular information contained within the NP corona is far richer than originally described and has been shown to contain a diverse array of biomolecules including proteins, lipids, metabolites and now cfDNA. This complex coating on the surface of NPs has the potential to be able to enhance nano-drug delivery and NP uptake, but perhaps most significantly, offers the potential to provide greater sensitivity for liquid biopsies.

This study has shown that cell-free DNA is present in the biomolecule corona that forms around lipid-based NPs, upon incubation with human plasma. The cfDNA content of the biomolecule corona could be directly quantified in the presence other biomolecules (e.g. proteins) using conventional real-time qPCR assays. Furthermore, proteomic analysis of the biomolecule corona by LC-MS/MS revealed the presence of nucleosome complex proteins, suggesting an indirect protein-mediated interaction of cfDNA with NPs. Notably, the amount of cfDNA was found to be significantly higher in the coronas formed in early- and late-stage cancer patient plasma samples compared to healthy controls, indicating a disease-specific biomolecule corona formation. This study highlights the potential exploitation of the biomolecule corona as a novel blood-analysis nanoscale tool and that multi-omic analysis can be carried out on the NP-corona, such as from a single sample, either sequentially or in parallel.

Example 2. A Multi-Omic Approach

Ongoing biomarker development efforts indicate that multiple markers, used individually or as part of a panel, are required to provide sufficient sensitivity and specificity for early disease detection. In addition, understanding the heterogeneous underlying mechanisms requires the integration of multiple omics approaches. Examining molecular alterations in blood at multiple dimensions (genome, proteome, metabolome etc.) and integrating the resultant multi-omics data not only has the potential to elucidate disease-specific molecular mechanisms and pathways, but also to uncover novel biomarkers to aid early disease detection, patient stratification and disease monitoring (Cohen J D et al., Science, 2018, 359,926-930; Hristova V A, Chan D W, Expert Rev Proteomics, 2019; 16(2)93-103).

Currently, one of the major bottlenecks for the multi-omics analysis of blood is the large volume of patient sample required (˜10-15 ml), in order to distinctly enrich and extract proteins, nucleic acids and lipids. This not only limits analytical reproducibility, but it also compromises the comparability of the resultant omics data sets. The minimally invasive blood collection procedures, coupled with the ability to perform integrative multi-omics analysis on a single specimen are tremendous advantages that could redefine the future of biomarker discovery. (Hristova V A, Chan D W, Expert Rev Proteomics, 2019; 16(2)93-103).

2.1 The NP-biomolecule coronas produced from the subjects in Example 1 were subjected to multi-omic analysis (genomic, proteomic and lipidomic) as described in the Materials and methods.

The data generated is shown in FIGS. 8-12 and in Tables 2-8 below. This demonstrates that a single processed sample can be subjected to multi-omic analysis. Analyzing a single sample source will facilitate more accurate comparison of data.

TABLE 2
Mass Spectrometry-based proteomic analysis. Full list of proteins identified by Scaffold
Software tool in healthy human plasma and onto the surface of PEG:HSPC:CHOL liposomes
classified from the highest relative protein abundance (RPA) to the lowest.
			RPA NP-	STDV NP-
	Accession	MW	Protein	Protein
Identified Proteins (n = 315)	Number	(kDa)	Corona	Corona
Full-length cDNA clone CS0DD006YL02 of	Q86TT1_HUMAN	41	5.59	0.09
Neuroblastoma of Homo sapiens (human)
Immunoglobulin heavy constant mu	IGHM_HUMAN	49	5.02	0.04
GN = IGHM
Lipoprotein B (Fragment) GN = APOB	S5FLF7_HUMAN	10	2.51	2.19
Immunoblobulin light chain (Fragment)	Q0KKI6_HUMAN	24	3.18	0.12
IGK@ protein	Q6PIL8_HUMAN	26	3.14	0.11
Immunoglobulin mu heavy chain	IGM_HUMAN	63	3.18	0.03
IGK@ protein	Q6P5S8_HUMAN	26	2.90	0.11
Immunoglobulin kappa light chain	IGK_HUMAN	23	2.86	0.12
Alpha-2-macroglobulin GN = A2M	A2MG_HUMAN	163	1.65	0.77
Fibrinogen beta chain GN = FGB	FIBB_HUMAN (+1)	56	1.66	0.41
Apolipoprotein B (Including Ag(X) antigen)	C0JYY2_HUMAN	516	1.33	0.92
GN = APOB
cDNA FLJ51597, highly similar to C4b-	B4E1D8_HUMAN	60	1.69	0.22
binding protein alpha chain
Fibrinogen gamma chain, isoform CRA_a	D3DP16_HUMAN	38	1.33	0.28
GN = FGG
IGHV4-34 protein (Fragment)	A0A0F7T737_HUMAN	11	1.57	0.17
GN = IGHV4-34	(+1)
Testicular tissue protein Li 70	A0A140VJJ6_HUMAN	49	1.15	0.24
IgG L chain	S6AWF4_HUMAN	20	1.18	0.06
IgG L chain	S6B294_HUMAN	20	1.16	0.07
IGL@ protein	Q8N5F4_HUMAN	25	1.29	0.09
Lambda-chain (AA −20 to 215)	A2NUT2_HUMAN	25	1.28	0.09
IGL@ protein	Q6PIQ7_HUMAN	25	0.39	0.68
IgG L chain	S6BAR0_HUMAN	23	1.17	0.10
IGL@ protein	Q6PIK1_HUMAN	25	1.11	0.03
IgG L chain	S6AWE6_HUMAN	23	1.13	0.10
Fibrinogen alpha chain GN = FGA	FIBA_HUMAN	95	0.90	0.16
Uncharacterized protein	Q8NEJ1_HUMAN	25	1.08	0.10
IGL@ protein	Q5FWF9_HUMAN	25	1.11	0.14
10E8 heavy chain variable region	A0A193CHQ9_HUMAN	14	1.07	0.20
(Fragment)
Anti-FactorVIII scFv (Fragment)	A2KBC6_HUMAN	25	0.93	0.08
Apolipoprotein E isoform 1 (Fragment)	A0A0S2Z3D5_HUMAN	36	0.98	0.11
	(+1)
Myosin-reactive immunoglobulin heavy	Q9UL90_HUMAN	12	0.95	0.17
chain variable region (Fragment)
GCT-A1 heavy chain variable region	A0A125U0V2_HUMAN	14	1.01	0.20
(Fragment)
Haptoglobin-related protein GN = HPR	HPTR_HUMAN	39	0.94	0.12
Anti-streptococcal/anti-myosin	Q96SA9_HUMAN	12	0.83	0.04
immunoglobulin kappa light chain
variable region (Fragment)
Rheumatoid factor RF-ET6 (Fragment)	A2J1N5_HUMAN	10	0.76	0.14
GCT-A5 light chain variable region	A0A0X9UWL5_HUMAN	12	0.72	0.11
(Fragment)
Immunoglobulin heavy variable 3-74	HV374_HUMAN	13	0.79	0.03
GN = IGHV3-74
Apolipoprotein A-I, isoform CRA_a	A0A024R3E3_HUMAN	31	0.80	0.04
N = APOA1	(+1)
Myosin-reactive immunoglobulin heavy	Q9UL88_HUMAN	14	0.47	0.40
chain variable region (Fragment)
A30 (Fragment)	A2MYE1_HUMAN (+1)	10	0.67	0.02
GCT-A4 light chain variable region	A0A0X9T7V9_HUMAN	12	0.73	0.13
(Fragment)
CD5 antigen-like GN = CD5L	CD5L_HUMAN	38	0.68	0.06
Haptoglobin GN = HP	HPT_HUMAN (+2)	45	0.69	0.06
Protein S isoform 1 (Fragment)	A0A0S2Z4K3_HUMAN	75	0.62	0.02
GN = PROS1	(+2)
Apolipoprotein D GN = APOD	APOD_HUMAN (+1)	21	0.55	0.05
IGH@ protein GN = IGH@	Q6GMX6_HUMAN	51	0.64	0.05
Epididymis luminal protein 214	V9HW68_HUMAN	52	0.58	0.03
GN = HEL-214
GCT-A6 heavy chain variable region	A0A109PVK5_HUMAN	15	0.53	0.06
(Fragment)
Myosin-reactive immunoglobulin light	Q9UL83_HUMAN	12	0.53	0.02
chain variable region (Fragment)
Immunglobulin heavy chain variable	Q0ZCI6_HUMAN	14	0.37	0.33
region (Fragment)
Variable immnoglobulin anti-estradiol	A2NZ55_HUMAN	14	0.18	0.31
heavy chain (Fragment)
Complement C3 GN = C3	CO3_HUMAN (+1)	187	0.48	0.03
IGHV3-72 protein (Fragment)	A0A0F7TAG7_HUMAN	12	0.53	0.05
GN = IGHV3-72	(+1)
Myosin-reactive immunoglobulin light	Q9UL70_HUMAN	12	0.47	0.04
chain variable region (Fragment)
Serum albumin GN = ALB	ALBU_HUMAN	69	0.52	0.03
cDNA FLJ14473 fis, clone	Q96K68_HUMAN	53	0.57	0.09
MAMMA1001080, highly similar to
Homo sapiens SNC73 protein (SNC73)
mRNA
Uncharacterized protein	Q6MZX9_HUMAN	52	0.48	0.01
DKFZp686M08189
GN = DKFZp686M08189
Single-chain Fv (Fragment) GN = scFv	Q65ZC9_HUMAN	26	0.16	0.27
Uncharacterized protein	A8K008_HUMAN	52	0.51	0.04
MS-D4 heavy chain variable region	A0A0X9UWK7_HUMAN	14	0.48	0.02
(Fragment)
Complement component 1, q	A0A024RAB9_HUMAN	27	0.45	0.01
subcomponent, B chain, isoform	(+3)
CRA_a GN = C1QB
cDNA FLJ41981 fis, clone	Q6ZVX0_HUMAN	53	0.46	0.02
SMINT2011888, highly similar to
Protein Tro alpha1 H, myeloma
Rheumatoid factor RF-ET9 (Fragment)	A2J1N6_HUMAN	13	0.52	0.05
Immunoglobulin heavy variable 3-73	HV373_HUMAN	13	0.41	0.06
GN = IGHV3-73
Immunoglobulin heavy chain variant	Q9NPP6_HUMAN	45	0.47	0.04
(Fragment)
IgG H chain	S6B291_HUMAN	51	0.47	0.03
Uncharacterized protein GN =	Q6N089_HUMAN	52	0.45	0.02
DKFZp686P15220
Cold agglutinin FS-1 L-chain (Fragment)	A2NB45_HUMAN	12	0.41	0.09
Immunoglobulin alpha-2 heavy chain	IGA2_HUMAN	49	0.40	0.01
Apolipoprotein C-III GN = APOC3	A3KPE2_HUMAN (+2)	11	0.39	0.02
IBM-B2 heavy chain variable region	A0A125QYY9_HUMAN	14	0.43	0.07
(Fragment)
Ig heavy chain variable region	A0A068LKQ2_HUMAN	13	0.47	0.11
(Fragment)
Immunoglobulin heavy variable 1-2	HV102_HUMAN	13	0.38	0.01
GN = IGHV1-2
Clusterin GN = CLU	CLUS_HUMAN	52	0.32	0.06
N90-VRC38.08 heavy chain variable	A0A1W6IYI5_HUMAN	14	0.38	0.05
region (Fragment)
Alpha-1-antitrypsin GN = SERPINA1	A0A024R6I7_HUMAN	47	0.30	0.07
Cryocrystalglobulin CC1 heavy chain	B1N7B6_HUMAN	13	0.35	0.02
variable region (Fragment)
Immunoglobulin heavy variable 3-13	HV313_HUMAN	13	0.31	0.05
GN = IGHV3-13
Immunoglobulin heavy variable 3-49	HV349_HUMAN	13	0.27	0.06
GN = IGHV3-49
Immunoglobulin heavy variable 1-46	HV146_HUMAN	13	0.26	0.06
GN = IGHV1-46
Immunoglobulin heavy variable 3-43	HV343_HUMAN	13	0.11	0.19
GN = IGHV3-43
Apolipoprotein C-IV GN = APOC4	A5YAK2_HUMAN	15	0.27	0.06
cDNA, FLJ94213, highly similar to	B2R950_HUMAN (+1)	164	0.23	0.11
Homo sapiens pregnancy-zone protein
(PZP), mRNA
Cryocrystalglobulin CC1 kappa light	B1N7B8_HUMAN	12	0.35	0.05
chain variable region (Fragment)
Apolipoprotein M GN = APOM	APOM_HUMAN	21	0.28	0.03
Apolipoprotein C-I, isoform CRA_a	A0A024R0T8_HUMAN	9	0.29	0.01
GN = APOC1	(+2)
VH6DJ protein (Fragment) GN = VH6DJ	A2N0T9_HUMAN	13	0.34	0.05
Immunoglobulin kappa variable 1-8	KV108_HUMAN	13	0.31	0.02
GN = IGKV1-8
Lectin galactoside-binding soluble 3	A0A0S2Z3Y1_HUMAN	65	0.26	0.02
binding protein isoform 1 (Fragment)	(+1)
GN = LGALS3BP
Complement C4-B GN = C4B	CO4B_HUMAN	193	0.25	0.03
Immunoglobulin J chain GN = JCHAIN	IGJ_HUMAN	18	0.31	0.07
Complement component 1, q	A0A024RAA7_HUMAN	26	0.26	0.01
subcomponent, C chain, isoform CRA_a	(+1)
GN = C1QC
VH6DJ protein (Fragment) GN = VH6DJ	A2N0U5_HUMAN	12	0.25	0.02
V1-2 protein (Fragment) GN = V1-2	A2MYD6_HUMAN	10	0.17	0.15
Complement C4-A GN = C4A	A0A0G2JPR0_HUMAN	193	0.24	0.03
Uncharacterized protein	Q6MZU6_HUMAN	51	0.30	0.04
DKFZp686C15213
GN = DKFZp686C15213
Immunoglobulin heavy variable 2-70D	HV70D_HUMAN	13	0.29	0.03
GN = IGHV2-70D
Apolipoprotein A-II GN = APOA2	APOA2_HUMAN (+3)	11	0.22	0.02
MS-A2 light chain variable region	A0A0X9V981_HUMAN	11	0.22	0.02
(Fragment)
cDNA FLJ75066, highly similar to	A8K5J8_HUMAN	80	0.20	0.04
Homo sapiens complement component
1, r subcomponent (C1R), mRNA
V1-3 protein (Fragment) GN = V1-3	Q5NV84_HUMAN	10	0.21	0.01
APOC4-APOC2 readthrough (NMD	K7ER74_HUMAN	20	0.20	0.02
candidate) GN = APOC4-APOC2
Anti-Influenza A hemagglutinin heavy	G1FM90_HUMAN	15	0.20	0.03
chain variable region (Fragment)
APOL1 protein (Fragment) GN = APOL1	A5PL32_HUMAN (+4)	49	0.19	0.02
Uncharacterized protein	Q6N030_HUMAN	57	0.23	0.02
GN = DKFZp686I15212
Immunoglobulin heavy variable 1-18	HV118_HUMAN	13	0.23	0.04
GN = IGHV1-18
GCT-A5 heavy chain variable region	A0A0X9T0H6_HUMAN	13	0.22	0.01
(Fragment)
Immunoglobulin kappa variable 2D-29	KVD29_HUMAN	13	0.14	0.12
GN = IGKV2D-29
cDNA, FLJ93914, highly similar to	B2R8I2_HUMAN	60	0.20	0.01
Homo sapiens histidine-rich glycoprotein
(HRG), mRNA
Rheumatoid factor RF-IP12 (Fragment)	A2J1M8_HUMAN	11	0.15	0.13
Actin, alpha cardiac muscle 1	ACTC_HUMAN	42	0.21	0.03
GN = ACTC1
Serum paraoxonase/arylesterase 1	PON1_HUMAN	40	0.19	0.01
GN = PON1
SAA2-SAA4 readthrough	A0A096LPE2_HUMAN	23	0.16	0.06
GN = SAA2-SAA4
Complement component 1, q	A0A024RAG6_HUMAN	26	0.18	0.02
subcomponent, A chain, isoform	(+1)
CRA_a GN = C1QA
Complement factor H GN = CFH	CFAH_HUMAN	139	0.12	0.09
Amyloid lambda 6 light chain variable	Q96JD1_HUMAN	12	0.21	0.02
region PIP (Fragment)
C4b-binding protein beta chain	C4BPB_HUMAN	28	0.18	0.03
GN = C4BPB
Fibronectin 1, isoform CRA_n	A0A024R462_HUMAN	259	0.12	0.10
GN = FN1	(+1)
Immunoglobulin kappa variable 1-16	KV116_HUMAN	13	0.19	0.04
GN = IGKV1-16
Immunoglobulin heavy variable 3-64D	HV64D_HUMAN	13	0.16	0.01
GN = IGHV3-64D
Immunoglobulin kappa variable 2D-24	A0A075B6R9_HUMAN	13	0.16	0.01
(non-functional) (Fragment) GN =	(+1)
IGKV2D-24
Immunoglobulin heavy variable 3-64	HV364_HUMAN	13	0.15	0.03
GN = IGHV3-64
Immunoglobulin heavy variable 2-26	HV226_HUMAN	13	0.14	0.03
GN = IGHV2-26
V1-13 protein (Fragment) GN = V1-13	Q5NV69_HUMAN	10	0.18	0.02
Apolipoprotein A-IV GN = APOA4	APOA4_HUMAN	45	0.18	0.03
V5-2 protein (Fragment) GN = V5-2	A2MYC8_HUMAN (+2)	11	0.19	0.07
Ficolin-3 GN = FCN3	FCN3 HUMAN	33	0.15	0.00
cDNA FLJ53075, highly similar to	B4DPP8_HUMAN (+1)	46	0.13	0.01
Kininogen-1
Immunoglobulin kappa variable 6-21	KV621_HUMAN	12	0.22	0.08
GN = IGKV6-21
Immunoglobulin heavy constant gamma	A0A286YFJ8_HUMAN	44	0.15	0.02
4 (Fragment) GN = IGHG4	(+1)
ADP/ATP translocase 3 GN =	ADT3_HUMAN (+2)	33	0.10	0.03
SLC25A6
Ig heavy chain variable region	A0A068LN03_HUMAN	13	0.19	0.06
(Fragment)
Immunoglobulin lambda variable 8-61	LV861_HUMAN (+1)	13	0.15	0.04
GN = IGLV8-61 PE = 3 SV = 7
Prenylcysteine oxidase 1 GN = PCYOX1	PCYOX_HUMAN	57	0.13	0.01
Transferrin variant (Fragment)	Q53H26_HUMAN	77	0.13	0.02
Lipoprotein, Lp(A) GN = LPA	Q1HP67_HUMAN	227	0.07	0.06
N90-VRC38.10 heavy chain variable	A0A1W6IYI8_HUMAN	14	0.13	0.02
region (Fragment)
N90-VRC38.05 heavy chain variable	A0A1W6IYJ2_HUMAN	14	0.06	0.06
region (Fragment)
cDNA FLJ56954, highly similar to	B7Z539_HUMAN	72	0.07	0.06
Inter-alpha-trypsin inhibitor heavy
chain H1
Angiotensinogen GN = AGT	ANGT_HUMAN (+6)	53	0.11	0.00
Ficolin-2 GN = FCN2	FCN2_HUMAN	34	0.12	0.02
Proteoglycan 4, isoform CRA_a	A0A024R930_HUMAN	151	0.07	0.04
GN = PRG4	(+2)
V4-2 protein (Fragment) GN = V4-2	Q5NV82_HUMAN	11	0.07	0.06
Polymeric immunoglobulin receptor	PIGR_HUMAN	83	0.11	0.01
GN = PIGR
Protein AMBP GN = AMBP	AMBP_HUMAN	39	0.07	0.03
Phosphatidylinositol-glycan-specific	PHLD_HUMAN	92	0.08	0.01
phospholipase D GN = GPLD1
Inter-alpha (Globulin) inhibitor H2	A2RTY6_HUMAN (+3)	106	0.05	0.05
GN = ITIH2
Actin, cytoplasmic 1 GN = ACTB	ACTB_HUMAN (+2)	42	0.11	0.04
Alpha-crystallin B chain GN = CRYAB	A0A024R3B9_HUMAN	12	0.06	0.05
	(+7)
Serum amyloid P-component GN =	SAMP_HUMAN (+1)	25	0.09	0.01
APCS
Complement factor properdin isoform 1	A0A0S2Z4I5_HUMAN	51	0.08	0.01
(Fragment) GN = CFP	(+1)
von Willebrand factor GN = VWF	VWF_HUMAN	309	0.06	0.04
Immunoglobulin heavy variable 2-5	HV205_HUMAN	13	0.06	0.05
GN = IGHV2-5
HCG2039812, isoform CRA_b (Fragment)	A0A0S2Z428_HUMAN	60	0.08	0.00
GN = KRT6A	(+2)
Transthyretin GN = TTR	A0A087WT59_HUMAN	20	0.08	0.02
	(+3)
Vitronectin GN = VTN	D9ZGG2_HUMAN (+1)	54	0.09	0.04
Coagulation factor XI GN = F11	FA11_HUMAN	70	0.07	0.03
IgGFc-binding protein GN = FCGBP	FCGBP_HUMAN	572	0.09	0.02
Coagulation factor V GN = F5	A0A0A0MRJ7_HUMAN	252	0.04	0.03
	(+1)
Complement C1s subcomponent GN = C1S	C1S_HUMAN	77	0.05	0.02
Alpha-2-antiplasmin GN = SERPINF2	A2AP_HUMAN	55	0.07	0.01
Epididymis tissue protein Li 173	E9KL26_HUMAN	55	0.05	0.02
GN = SERPING1	(+1)
Serpin peptidase inhibitor, clade A (Alpha-	A0A024R6P0_HUMAN	48	0.09	0.02
1 antiproteinase, antitrypsin), member	(+2)
3, isoform CRA_c GN = SERPINA3
Alpha-1-acid glycoprotein 2 GN = ORM2	A1AG2_ HUMAN	24	0.04	0.03
Lipopolysaccharide-binding protein	LBP_HUMAN (+1)	53	0.06	0.00
GN = LBP
CP protein GN = CP	A5PL27_HUMAN (+5)	122	0.05	0.01
cDNA FLJ76342, highly similar to	A8K1K1_HUMAN (+1)	57	0.06	0.00
Homo sapiens carnosine dipeptidase 1
(metallopeptidase M20 family)
(CNDP1), mRNA
Platelet-activating factor acetylhydrolase	A0A024RD39_HUMAN	50	0.04	0.01
GN = PLA2G7	(+1)
Anoctamin (Fragment) GN = ANO7	H7C220_HUMAN	21	0.02	0.03
PE = 3 SV = 8
Serpin peptidase inhibitor, clade C	A0A024R944_HUMAN	53	0.05	0.00
(Antithrombin), member 1, isoform CRA_a	(+2)
GN = SERPINC1
ATP synthase subunit alpha, mitochondrial	ATPA_HUMAN (+1)	60	0.03	0.01
GN = ATP5A1
Adiponectin GN = ADIPOQ	A8K660_HUMAN (+2)	26	0.03	0.03
Carboxypeptidase N catalytic chain	CBPN_HUMAN	52	0.02	0.02
GN = CPN1
Mannan-binding lectin serine protease	MASP1_HUMAN	79	0.04	0.01
1 GN = MASP1
cDNA FLJ77947, highly similar to	A8K9M5_HUMAN (+6)	67	0.03	0.01
Human complement protein C8 beta
subunit mRNA
Complement C5 GN = C5	CO5_HUMAN	188	0.04	0.00
Soluble scavenger receptor cysteine-rich	SRCRL_HUMAN	166	0.02	0.02
domain-containing protein SSC5D
GN = SSC5D
Inter-alpha (Globulin) inhibitor H4	B2RMS9_HUMAN (+1)	103	0.03	0.01
(Plasma Kallikrein-sensitive
glycoprotein) GN = ITIH4
Adipocyte plasma membrane-associated	APMAP_HUMAN (+1)	46	0.03	0.01
protein GN = APMAP
Complement component 9, isoform	A0A024R035_HUMAN	63	0.05	0.02
CRA_a GN = C9	(+1)
Prothrombin GN = F2	E9PIT3_HUMAN (+1)	65	0.05	0.03
ATPase Ca++ transporting cardiac	A0A0S2Z3L_2_HUMAN	115	0.03	0.00
muscle slow twitch 2 isoform 1	(+1)
(Fragment) GN = ATP2A2
Hepatocyte growth factor activator	HGFA_HUMAN	71	0.03	0.01
GN = HGFAC
Collagen alpha-1(VI) chain	A0A087X0S5_HUMAN	108	0.03	0.01
GN = COL6A1	(+1)
Plasminogen GN = PLG	PLMN_HUMAN	91	0.03	0.01
Myosin-6 GN = MYH6	MYH6_HUMAN	224	0.02	0.00
Heparin cofactor 2 GN = SERPIND1	HEP2_HUMAN	57	0.03	0.00
Carboxypeptidase N subunit 2 GN = CPN2	CPN2_HUMAN	61	0.03	0.01
N-acetylmuramoyl-L-alanine amidase	PGRP2_HUMAN	62	0.04	0.01
GN = PGLYRP2
Collagen alpha-3(VI) chain GN =	CO6A3_HUMAN (+1)	344	0.02	0.01
COL6A3
Serpin peptidase inhibitor, clade A	A0A024R6I9_HUMAN	49	0.03	0.01
(Alpha-1 antiproteinase, antitrypsin),	(+2)
member 4, isoform CRA_a
GN = SERPINA4
Coagulation factor XIII B chain	F13B_HUMAN	76	0.02	0.00
GN = F13B
CDNA FLJ55769, highly similar to	B4DY96_HUMAN	51	0.02	0.00
Trifunctional enzyme subunit beta,	(+1)
mitochondrial
Angiopoietin-like 6, isoform CRA_a	A0A024R7A9_HUMAN	52	0.06	0.04
GN = ANGPTL6	(+1)
Alpha-1B-glycoprotein GN = A1BG	A1BG_HUMAN (+1)	54	0.02	0.02
CDNA FLJ53494, highly similar to	B4DN90_HUMAN	82	0.02	0.00
Cartilage oligomeric matrix protein	(+2)
Cholesteryl ester transfer protein plasma	A0A0S2Z3F6_HUMAN	55	0.03	0.01
isoform 1 (Fragment) GN = CETP	(+2)
Coagulation factor XIII A chain	F13A_HUMAN	83	0.02	0.01
GN = F13A1
Immunoglobulin delta heavy chain	IGD_HUMAN	56	0.02	0.01
Complement component C8 alpha chain	CO8A_HUMAN	65	0.02	0.01
GN = C8A
Inter-alpha-trypsin inhibitor heavy	ITIH3_HUMAN	100	0.02	0.00
chain H3 GN = ITIH3
Protein HEG homolog 1 GN = HEG1	HEG1_HUMAN	147	0.01	0.01
TNC variant protein (Fragment)	Q4LE33_HUMAN	244	0.01	0.01
GN = TNC variant protein
cDNA FLJ75881, highly similar to	A8K6Q8_HUMAN (+1)	85	0.01	0.00
Homo sapiens transferrin receptor (p90,
CD71) (TFRC), mRNA
Thrombospondin-1 GN = THBS1	TSP1_HUMAN	129	0.01	0.01
Prolow-density lipoprotein receptor-	LRP1_HUMAN	505	0.01	0.00
related protein 1 GN = LRP1
Reelin GN = RELN	J3KQ66_HUMAN (+1)	388	0.00	0.00
Laminin subunit beta-1 GN = LAMB1	G3XAI2_HUMAN (+1)	200	0.00	0.00
Sushi, von Willebrand factor type A,	A0A0A0MSD0_HUMAN	390	0.00	0.00
EGF and pentraxin domain-containing	(+2)
protein 1 GN = SVEP1
Desmoplakin GN = DSP	DESP_HUMAN	332	0.00	0.00
Junction plakoglobin, isoform CRA_a	A0A024R1X8_HUMAN	82	0.00	0.00
GN = JUP	(+2)
Glyceraldehyde-3-phosphate	G3P_HUMAN (+1)	36	0.00	0.00
dehydrogenase GN = GAPDH
Histone H4 GN = HIST1H4H	B2R4R0_HUMAN (+2)	11	0.00	0.00
Keratinocyte proline-rich protein	KPRP_HUMAN	64	0.00	0.00
GN = KPRP
Plakophilin 1 (Ectodermal dysplasia/skin	A0A024R952_HUMAN	80	0.00	0.00
fragility syndrome), isoform CRA_a
GN = PKP1
Histone H2B GN = HIST1H2BJ	A0A024RCJ2_HUMAN	14	0.00	0.00
	(+4)
Desmoglein-1 GN = DSG1	DSG1_HUMAN	114	0.00	0.00
Galectin-7 GN = LGALS7	LEG7_HUMAN	15	0.00	0.00
Histone H3 GN = H3F3B	B2R4P9_HUMAN (+10)	15	0.00	0.00
Calmodulin-like protein 3 GN =	CALL3_HUMAN	17	0.00	0.00
CALML3
Annexin GN = ANXA2	A0A024R5Z7_HUMAN	39	0.00	0.00
	(+2)
ATP synthase subunit beta,	ATPB_HUMAN (+2)	57	0.00	0.00
mitochondrial GN = ATP5B
Liver histone H1e	A3R0T7_HUMAN (+6)	22	0.00	0.00
cDNA FLJ43122 fis, clone	B3KWI4_ HUMAN (+1)	64	0.00	0.00
CTONG3003737, highly similar to
Leucine-rich repeat-containing protein 15
14-3-3 protein sigma GN = SFN	1433S_HUMAN	28	0.00	0.00
V-set and immunoglobulin domain-	VSIG8_HUMAN	44	0.00	0.00
containing protein 8 GN = VSIG8
Heat shock cognate 71 kDa protein	E9PKE3_HUMAN (+2)	69	0.00	0.00
GN = HSPA8
Heat shock protein beta-1 GN = HSPB1	HSPB1_HUMAN (+1)	23	0.00	0.00
Histone H1.5 GN = HIST1H1B	H15_HUMAN	23	0.00	0.00
Peroxiredoxin-6 GN = PRDX6	PRDX6_HUMAN (+1)	25	0.00	0.00
Galectin GN = hCG_22119	A0A024R693_HUMAN	26	0.00	0.00
	(+6)
60S ribosomal protein L8 GN = RPL8	RL8_HUMAN	28	0.00	0.00
Serpin B12 GN = SERPINB12	SPB12_HUMAN	46	0.00	0.00
Elongation factor 1-alpha 1 GN = EEF1A1	EF1A1_HUMAN (+8)	50	0.00	0.00
Tubulin alpha-1A chain GN = TUBA1A	TBA1A_HUMAN	50	0.00	0.00
Voltage-dependent anion channel 2,	A0A024QZN9_HUMAN	34	0.00	0.00
isoform CRA_a GN = VDAC2	(+3)
Cytosol aminopeptidase GN = LAP3	AMPL_HUMAN (+1)	56	0.00	0.00
Protein-glutamine gamma-	TGM3_HUMAN	77	0.00	0.00
glutamyltransferase E GN = TGM3
Desmoglein-4 GN = DSG4	DSG4_HUMAN	114	0.00	0.00
Serine protease inhibitor Kazal-type 5	ISK5_HUMAN	121	0.00	0.00
GN = SPINK5
Band 3 anion transport protein	B3AT_HUMAN (+3)	102	0.00	0.00
GN = SLC4A1
Hephaestin-like protein 1 GN = HEPHL1	HPHL1_HUMAN	132	0.00	0.00
APOB protein GN = APOB	Q7Z7Q0_HUMAN	92	0.52	0.89
IGL@ protein	Q8N355_HUMAN	25	0.45	0.78
cDNA FLJ90170 fis, clone	Q8NCL6_HUMAN	53	0.37	0.32
MAMMA1000370, highly similar to
Ig alpha-1 chain C region
V2-17 protein (Fragment) GN = V2-17	Q5NV90_HUMAN	10	0.31	0.29
Immunoglobulin heavy variable 3-53	HV353_HUMAN (+1)	13	0.30	0.52
GN = IGHV3-53
IGHV1-2 protein (Fragment)	A0A0F776Q1_HUMAN	12	0.23	0.20
GN = IGHV1-2
Anti-(ED-B) scFV (Fragment)	A2KBC1_HUMAN	25	0.22	0.37
Anti-HER3 scFv (Fragment)	A2J422_HUMAN	26	0.21	0.18
Immunoglobulin kappa variable 4-1	KV401_HUMAN	13	0.21	0.36
GN = IGKV4-1
Rheumatoid factor RF-IP4 (Fragment)	A2J1M5_HUMAN	10	0.20	0.35
V5-6 protein (Fragment) GN = V5-6	Q5NV92_HUMAN	11	0.19	0.17
Immunoglobulin kappa variable 3D-20	KVD20_HUMAN	13	0.18	0.32
GN = IGKV3D-20
NANUC-2 heavy chain (Fragment)	A2NKM7_HUMAN	15	0.18	0.15
Uncharacterized protein	Q6N092_HUMAN	56	0.16	0.28
DKFZp686K18196 (Fragment)
GN = DKFZp686K18196
Uncharacterized protein	Q6N091_HUMAN	54	0.14	0.12
DKFZp686C02220 (Fragment)
GN = DKFZp686C02220
Uncharacterized protein	Q6N094_HUMAN	53	0.13	0.23
DKFZp686O01196
GN = DKFZp686O01196
Uncharacterized protein	Q7Z379_HUMAN	52	0.12	0.21
DKFZp686K04218 (Fragment)
GN = DKFZp686K04218
10E8 light chain variable region	A0A193CHR5_HUMAN	12	0.10	0.09
(Fragment)	(+3)
MS-D2 light chain variable region	A0A0X9USL5_HUMAN	11	0.09	0.09
(Fragment)
Rheumatoid factor RF-ET12 (Fragment)	A2J1N9_HUMAN	11	0.09	0.16
IgG H chain	S6BAM6_HUMAN	34	0.09	0.15
IgG H chain	S6BGE0_HUMAN	32	0.08	0.15
IBM-B2 light chain variable region	A0A0X9V9D6_HUMAN	11	0.08	0.07
(Fragment)
Myosin-reactive immunoglobulin kappa	Q9UL86_HUMAN	12	0.08	0.13
chain variable region (Fragment)
GCT-A2 heavy chain variable region	A0A125U0V4_HUMAN	14	0.07	0.13
(Fragment)
Immunoglobulin heavy variable 1-69	HV169 HUMAN	13	0.06	0.11
GN = IGHV1-69
Immunoglobulin heavy variable 3-35	A0A0C4DH35_HUMAN	13	0.05	0.09
(non-functional) (Fragment)
GN = IGHV3-35
Anti-folate binding protein (Fragment)	A2NYQ7_HUMAN (+2)	11	0.05	0.08
GN = HuC4lambda Vlambda
Cryocrystalglobulin CC2 lambda light	B1N7B9_HUMAN	11	0.05	0.08
chain variable region (Fragment)
Beta-2-glycoprotein 1 GN = APOH	APOH_HUMAN (+1)	38	0.04	0.04
Immunoglobulin kappa variable 1-13	KV113_HUMAN (+1)	13	0.04	0.07
GN = IGKV1-13
Heavy chain Fab (Fragment)	A2NYU7_HUMAN	14	0.04	0.06
IBM-A2 light chain variable region	A0A0X9T0I7_HUMAN	12	0.03	0.05
(Fragment)
Immunoglobulin kappa variable 1D-16	KVD16_HUMAN	13	0.03	0.05
(Fragment) GN = IGKV1D-16
IBM-B3 heavy chain variable region	A0A109PW50_HUMAN	14	0.02	0.04
(Fragment)
N90-VRC38.07 heavy chain variable	A0A1W6IYI6_HUMAN	14	0.02	0.04
region (Fragment)
Serum amyloid A protein GN = SAA1	D3DQX7_HUMAN	14	0.02	0.04
Myosin, light polypeptide 3, alkali	A0A024R2Q5_HUMAN	22	0.02	0.04
ventricular, skeletal, slow, isoform	(+1)
CRA_a GN = MYL3
40S ribosomal protein (Fragment)	A0A248RGE3_HUMAN	17	0.02	0.04
	(+34)
Beta-globin GN = HBB	D9YZU5_HUMAN (+1)	16	0.02	0.04
Hemopexin GN = HPX	HEMO_HUMAN	52	0.02	0.02
Serpin peptidase inhibitor, clade A	A0A024R6N9_HUMAN	46	0.02	0.02
(Alpha-1 antiproteinase, antitrypsin),	(+1)
member 5, isoform CRA_a
GN = SERPINA5
CDNA FLJ55606, highly similar to	B7Z8Q2_HUMAN (+2)	47	0.02	0.02
Alpha-2-HS-glycoprotein
Collectin sub-family member 10 (C-type	A0A024R9J3_HUMAN	31	0.02	0.03
lectin), isoform CRA_a GN = COLEC10	(+1)
Sperm binding protein 1a	A0A1L1UHR1_HUMAN	31	0.02	0.03
	(+1)
Apolipoprotein F GN = APOF	APOF_HUMAN (+1)	35	0.01	0.03
Uncharacterized protein	Q6MZL2_HUMAN	35	0.01	0.03
DKFZp686M0562 (Fragment)
GN = DKFZp686M0562
Mannose-binding protein C GN = MBL2	MBL2_HUMAN	26	0.01	0.02
HLA class I histocompatibility antigen,	A0A140T951_HUMAN	27	0.01	0.02
B-46 alpha chain (Fragment)
GN = HLA-B
Apolipoprotein A-V, isoform CRA_a	A0A0B4RUS7_HUMAN	41	0.01	0.02
GN = APOA5	(+3)
Phospholipid transfer protein, isoform	B3KUE5_HUMAN (+2)	57	0.01	0.01
CRA_c GN = PLTP
Gelsolin GN = GSN	A0A0A0MS51_HUMAN	83	0.01	0.02
	(+5)
cDNA FLJ51409, highly similar to	B7Z832_HUMAN (+2)	96	0.01	0.01
Thrombospondin-4
Stomatin, isoform CRA_a GN = STOM	A0A024R882_HUMAN	32	0.01	0.02
	(+3)
Selenoprotein P (Fragment) GN =	A0A182DWH7_HUMAN	35	0.01	0.02
SELENOP	(+1)
Guanine nucleotide binding protein (G	A0A024R056_HUMAN	37	0.01	0.02
protein), beta polypeptide 1, isoform	(+2)
CRA_a GN = GNB1
cDNA FLJ78207, highly similar to	A8K2T4_HUMAN (+2)	93	0.01	0.02
Human complement protein component
C7 mRNA
Protein disulfide-isomerase GN = P4HB	A0A024R8S5_HUMAN	57	0.01	0.02
	(+1)
Oncoprotein-induced transcript 3 protein	OIT3_HUMAN	60	0.01	0.01
GN = OIT3
Integrin alpha-Ilb GN = ITGA2B	ITA2B_HUMAN	113	0.01	0.01
Moesin GN = MSN	MOES_HUMAN (+1)	68	0.01	0.01
Afamin GN = AFM	AFAM_HUMAN	69	0.01	0.01
Insulin-like growth factor-binding	ALS_HUMAN (+2)	66	0.01	0.01
protein complex acid labile subunit
GN = IGFALS
Cartilage acidic protein 1 GN = CRTAC1	A0A0C4DFP6_HUMAN	70	0.00	0.01
	(+1)
cDNA FLJ78071, highly similar to	A8K8Z4_HUMAN (+1)	105	0.00	0.01
Human MHC class III complement
component C6 mRNA
cDNA FLJ77744, highly similar to	A8K9A9_HUMAN (+2)	71	0.00	0.01
Homo sapiens kallikrein B, plasma
(Fletcher factor) 1 (KLKB1), mRNA
Fermitin family homolog 3 GN =	URP2_HUMAN	76	0.00	0.01
FERMT3
Integrin beta	B4DTY9_HUMAN (+3)	84	0.00	0.01
CFB	A0A1U9X7H2_HUMAN	86	0.00	0.01
	(+9)
Collagen alpha-2(VI) chain GN =	CO6A2_HUMAN	109	0.00	0.01
COL6A2
Laminin, gamma 1 (Formerly LAMB2),	A0A024R972_HUMAN	174	0.00	0.00
isoform CRA_a GN = LAMC1	(+1)
Titin GN = TTN	A0A0A0MTS7_HUMAN	3994	0.00	0.00
	(+3)

TABLE 3
Candidate corona protein biomarkers differentially expressed between healthy controls and early stage
ovarian carcinoma patients, as identified by proteomic analysis of the ex vivo NP coronas.
Full list of proteins identified by Progenesis QI for proteomics to be upregulated or downregulated in
early stage ovarian carcinoma patients in comparison with healthy controls classified from the highest
max fold-change to the lowest. Only proteins with p < 0.05 are shown.
		Anova	Max fold
Identified Protein (n = 202)	Accession Number	(p)	change
UPREGULATED (n = 69)
Vimentin GN = VIM	VIME_HUMAN	8.57E−06	55.78
Anion exchange protein GN = SLC4A1	E2RVJ0_HUMAN	3.00E−06	34.13
Elongation factor 1-alpha (Fragment)	Q53GE9_HUMAN	1.35E−04	27.26
Signal recognition particle 54 kDa protein	G3V4F7_HUMAN	2.18E−02	27.17
GN = SRP54
Serum amyloid A-1 protein GN = SAA1	SAA1_HUMAN	2.87E−02	26.67
Histone H2A GN = HIST1H2AC	A0A024R017_HUMAN	2.23E−04	25.63
EPB41 protein (Fragment) GN = EPB41	Q1WWM3_HUMAN	6.88E−05	20.80
Spectrin beta chain GN = SPTB	B2RMN7_HUMAN	3.68E−05	20.46
Glycophorin GN = GPErik	Q14440_HUMAN	1.58E−03	16.29
Myosin-11 GN = MYH11	MYH11_HUMAN	8.45E−05	16.19
Keratin, type II cytoskeletal 75 GN = KRT75	K2C75_HUMAN	9.25E−04	14.71
cDNA FLJ50805, highly similar to Erythrocyte	B7Z4C3_HUMAN	2.41E−04	14.45
membrane protein band 4.2
Tubulin beta chain (Fragment)	Q6LC01_HUMAN	1.22E−03	14.33
Hemoglobin subunit beta GN = HBB	HBB_HUMAN	2.42E−07	10.86
Spectrin alpha chain, erythrocytic 1 GN =	SPTA1_HUMAN	7.41E−05	10.48
SPTA1
Mutant hemoglobin alpha 2 globin chain	A0A0K2BMD8_HUMAN	5.91E−07	9.35
GN = HBA2
Solute carrier family 2 (Facilitated glucose	Q0P512_HUMAN	7.17E−04	9.13
transporter), member 1 GN = SLC2A1
Tubulin beta-1 chain GN = TUBB1	TBB1_HUMAN	2.48E−02	8.65
Histone H2B type 1-B GN = HIST1H2BB	H2B1B_HUMAN	4.94E−04	8.57
Tubulin alpha-1A chain GN = TUBA1A	TBA1A_HUMAN	1.16E−03	7.55
Epididymis luminal protein 4 GN = YWHAZ	D0PNI1_HUMAN	1.40E−04	6.83
L-lactate dehydrogenase B chain GN = LDHB	LDHB_HUMAN	2.59E−04	6.75
Aminopeptidase GN = ANPEP	A0A024RC61_HUMAN	1.15E−02	6.54
Histone H4 GN = HIST1H4H	B2R4R0_HUMAN	1.23E−02	6.31
Peptidyl-prolyl cis-trans isomerase A GN =	PPIA_HUMAN	4.76E−04	6.00
PPIA
Actin, cytoplasmic 1 GN = ACTB	ACTB HUMAN	9.69E−05	5.89
Actin, aortic smooth muscle GN = ACTA2	ACTA_HUMAN	9.30E−05	5.83
Pyruvate kinase PKLR GN = PKLR	KPYR_HUMAN	2.26E−02	5.72
cDNA FLJ44538 fis, clone UTERU3005159,	B3KX26_HUMAN	4.48E−02	5.10
highly similar to TNF receptor-associated
factor 5
Coagulation factor XI GN = F11	FA11_HUMAN	2.11E−04	5.05
Catalase GN = CAT	CATA_HUMAN	1.96E−04	4.55
ARP3 actin-related protein 3 homolog (Yeast),	A0A024RAI1_HUMAN	6.33E−03	4.32
isoform CRA_a GN = ACTR3
Integrin beta-3 GN = ITGB3	ITB3_HUMAN	2.80E−03	4.31
cDNA FLJ38781 fis, clone LIVER2000216,	B3KTV0_HUMAN	8.53E−04	4.11
highly similar to HEAT SHOCK COGNATE
71 kDa PROTEIN
Ankyrin-1 GN = ANK1	ANK1_HUMAN	4.65E−03	4.07
Immunoglobulin heavy variable 3/OR16-12	A0A075B7B8_HUMAN	5.45E−04	4.07
(non-functional) (Fragment) GN =
IGHV3OR16-12
Glycoprotein Ib (Platelet), alpha polypeptide	A0A0C4DGZ8_HUMAN	9.52E−05	3.86
GN = GP1BA
Tyrosine-protein kinase receptor GN = TPM3-	M1VPF4_HUMAN	3.62E−02	3.76
ROS1
RAP1B, member of RAS oncogene family,	A0A024RB87_HUMAN	3.01E−03	3.60
isoform CRA_a GN = RAP1B
Multimerin-1 GN = MMRN1	MMRN1_HUMAN	7.47E−03	3.43
Integrin alpha-Ilb GN = ITGA2B	ITA2B_HUMAN	2.45E−02	3.19
Apolipoprotein C-III GN = APOC3	BOYIW2_HUMAN	2.87E−03	3.11
Ficolin-3 GN = FCN3	FCN3_HUMAN	2.20E−02	3.07
Integrin beta-1 GN = ITGB1	ITB1_HUMAN	1.63E−03	3.01
APOC4-APOC2 readthrough (NMD candidate)	K7ER74_HUMAN	8.63E−04	3.01
GN = APOC4-APOC2
Reelin GN = RELN	RELN_HUMAN	1.38E−03	2.98
Lipopolysaccharide-binding protein GN = LBP	LBP_HUMAN	7.17E−03	2.96
cDNA FLJ39539 fis, clone PUAEN2008228,	B3KUB8_HUMAN	2.53E−02	2.95
highly similar to Platelet glycoprotein 4
Glyceraldehyde-3-phosphate dehydrogenase	G3P_HUMAN	1.42E−02	2.91
GN = GAPDH
Thrombospondin-1 GN = THBS1	TSP1_HUMAN	4.01E−02	2.73
Thrombospondin 1, isoform CRA_a GN =	A0A024R9Q1_HUMAN	4.01E−02	2.73
THBS1
Moesin GN = MSN	MOES_HUMAN	3.66E−03	2.63
Sushi, von Willebrand factor type A, EGF	SVEP1_HUMAN	2.63E−03	2.47
and pentraxin domain-containing protein 1
GN = SVEP1
Apolipoprotein A-V, isoform CRA_a	A0A0B4RUS7_HUMAN	1.11E−02	2.47
GN = APOA5
Apolipoprotein C-I, isoform CRA_a	A0A024R0T8_HUMAN	2.68E−02	2.47
GN = APOC1
Filamin-A GN = FLNA	FLNA_HUMAN	6.29E−03	2.46
Hemicentin-1 GN = HMCN1	HMCN1_HUMAN	2.27E−03	2.46
Apolipoprotein C-IV GN = APOC4	APOC4_HUMAN	4.16E−03	2.30
cDNA FLJ60461, highly similar to	B4DF70_HUMAN	3.77E−02	2.24
Peroxiredoxin-2 (EC 1.11.1.15)
Apolipoprotein M GN = APOM	APOM_HUMAN	1.41E−02	2.03
Peroxisomal bifunctional enzyme GN =	ECHP_HUMAN	6.55E−04	1.89
EHHADH
78 kDa glucose-regulated protein GN =	GRP78_HUMAN	1.38E−02	1.84
HSPA5
Apolipoprotein C-IV GN = APOC4	A5YAK2_HUMAN	1.11E−02	1.69
Platelet-activating factor acetylhydrolase	A0A024RD39_HUMAN	1.66E−03	1.62
GN = PLA2G7
Apolipoprotein F GN = APOF	APOF_HUMAN	3.12E−02	1.61
Vascular endothelial growth factor receptor 3	VGFR3_HUMAN	3.03E−02	1.61
GN = FLT4
Complement component 1, r subcomponent	Q53HT9_HUMAN	4.21E−02	1.46
variant (Fragment)
cDNA FLJ75066, highly similar to Homo	A8K5J8_HUMAN	4.21E−02	1.46
sapiens complement component 1, r
subcomponent (C1R), mRNA
cAMP-responsive element modulator	H7C4X0_HUMAN	4.17E−02	1.38
(Fragment) GN = CREM
DOWNREGULATED (n = 133)
Regucalcin GN = RGN	RGN_HUMAN	6.04E−04	160.83
Retinol-binding protein 4 GN = RBP4	RET4_HUMAN	1.51E−02	36.24
AKAP350C	Q96KG3_HUMAN	1.63E−02	28.97
Beta-Ala-His dipeptidase GN = CNDP1	CNDP1_HUMAN	1.26E−13	16.58
E3 ubiquitin-protein ligase TRIM56	TRI56_HUMAN	5.43E−05	10.90
GN = TRIM56
Afamin GN = AFM	AFAM_HUMAN	2.23E−02	5.17
Uncharacterized protein GN =	Q6N095_HUMAN	3.59E−02	4.87
DKFZp686K03196
Transferrin variant (Fragment)	Q53H26_HUMAN	5.67E−03	4.62
cDNA, FLJ93914, highly similar to Homo	B2R8I2_HUMAN	4.16E−06	4.37
sapiens histidine-rich glycoprotein (HRG),
mRNA
Histidine-rich glycoprotein GN = HRG	HRG_HUMAN	4.16E−06	4.37
Vitamin D-binding protein GN = GC	D6RF35_HUMAN	1.52E−02	4.31
A disintegrin and metalloproteinase with	ATS13_HUMAN	7.51E−03	4.00
thrombospondin motifs 13 GN = ADAMTS13
Integrator complex subunit 4 GN = INTS4	INT4_HUMAN	2.42E−04	3.56
Plasminogen GN = PLG	PLMN_HUMAN	1.03E−03	3.55
Phosphatidylinositol-glycan-specific	PHLD_HUMAN	3.65E−08	3.41
phospholipase D GN = GPLD1
UBX domain-containing protein 8	A0A087WWA4_HUMAN	1.27E−02	3.30
(Fragment) GN = UBXN8
V5-6 protein (Fragment) GN = V5-6	Q5NV92_HUMAN	1.77E−02	3.27
Serum albumin GN = ALB	ALBU_HUMAN	1.48E−02	3.22
Selenoprotein P (Fragment) GN = SELENOP	A0A182DWH7_HUMAN	3.23E−08	3.08
Serpin peptidase inhibitor, clade C	A0A024R944_HUMAN	1.36E−03	3.07
(Antithrombin), member 1, isoform CRA_a
GN = SERPINC1
Transthyretin GN = TTR	A0A087WV45_HUMAN	8.04E−07	3.05
Immunoglobulin heavy variable 3-43	HV343_HUMAN	8.21E−04	2.94
GN = IGHV3-43
cDNA FLJ53691, highly similar to	B4E1B2_HUMAN	2.42E−02	2.84
Serotransferrin
Apolipoprotein A-IV GN = APOA4	APOA4_HUMAN	3.29E−04	2.78
Immunoglobulin kappa variable 3D-20	KVD20_HUMAN	1.02E−02	2.74
GN = IGKV3D-20
APOB protein (Fragment) GN = APOB	P78482_HUMAN	6.33E−03	2.71
Coagulation factor XII GN = F12	A0A0R7FJH5_HUMAN	6.12E−03	2.69
Immunoglobulin kappa variable 6D-21	KVD21_HUMAN	5.36E−03	2.68
GN = IGKV6D-21
Complement component C8 gamma	CO8G_HUMAN	2.18E−03	2.64
chain GN = C8G
Vitronectin GN = VTN	VTNC_HUMAN	3.92E−07	2.62
Uncharacterized protein	Q6MZL2_HUMAN	1.60E−04	2.55
DKFZp686M0562 (Fragment)
GN = DKFZp686M0562
Serpin peptidase inhibitor, clade A (Alpha-	A0A024R6N9_HUMAN	1.52E−04	2.54
1 antiproteinase, antitrypsin), member 5,
isoform CRA_a GN = SERPINA5
Mannan-binding lectin serine protease 1	MASP1_HUMAN	2.39E−04	2.44
GN = MASP1
cDNA FLJ59854, highly similar to	B4DEU0_HUMAN	8.17E−05	2.41
Homo sapiens pitrilysin metallopeptidase
1 (PITRM1), mRNA
N-acetylmuramoyl-L-alanine amidase	PGRP2_HUMAN	5.74E−06	2.39
GN = PGLYRP2
Rheumatoid factor light chain variable	A2NW98_HUMAN	3.30E−03	2.37
region (Fragment)
Heavy chain Fab (Fragment)	A2NYV1_HUMAN	4.24E−04	2.34
IBM-A2 heavy chain variable region	A0A0X9T7Y9_HUMAN	3.62E−02	2.33
(Fragment)
Anoctamin (Fragment) GN = ANO7	H7C220_HUMAN	4.51E−05	2.32
Complement component C7 GN = C7	CO7_HUMAN	1.59E−03	2.32
Immunoglobulin kappa variable 2D-2	KVD29_HUMAN	5.04E−04	2.31
GN = IGKV2D-29
Immunoglobulin heavy constant	IGHG2_HUMAN	1.59E−03	2.29
gamma 2 GN = IGHG2
Uncharacterized protein	Q6N093_HUMAN	1.59E−03	2.29
DKFZp686I04196 (Fragment)
GN = DKFZp686I04196
Uncharacterized protein	Q6MZU6_HUMAN	1.59E−03	2.29
DKFZp686C15213
GN = DKFZp686C15213
C4B (Fragment) GN = C4B	Q6U2L6_HUMAN	6.10E−03	2.26
Serum paraoxonase/arylesterase 1	PON1_HUMAN	3.90E−05	2.22
GN = PON1
Alpha-1-antitrypsin GN = SERPINA1	A0A024R6I7_HUMAN	9.75E−03	2.20
Alpha-1-antitrypsin GN = SERPINA1	A1AT_HUMAN	9.75E−03	2.20
GCT-A8 light chain variable region	A0A109PS54_HUMAN	4.26E−02	2.20
(Fragment)
Epididymis luminal protein 213	V9HW34_HUMAN	7.23E−04	2.20
GN = HEL-213
Probable ATP-dependent RNA helicase	A0A0C4DG89_HUMAN	8.49E−06	2.19
DDX46 GN = DDX46
REV25-2 (Fragment)	A0N7J6_HUMAN	4.42E−03	2.18
IGK@ protein GN = IGK@	Q6P5S8_HUMAN	1.98E−03	2.15
Immunoglobulin lambda variable 7-46	LV746_HUMAN	9.26E−03	2.13
GN = IGLV7-46
Rho GTPase-activating protein 23	A0A087WXU2_HUMAN	7.21E−04	2.10
(Fragment) GN = ARHGAP23
Angiotensinogen variant (Fragment)	Q53GY3_HUMAN	3.78E−03	2.10
Ceruloplasmin GN = CP	CERU_HUMAN	1.36E−02	2.08
Ig heavy chain variable region	A0A068LKQ2_HUMAN	9.38E−04	2.07
(Fragment)
Immunoglobulin lambda variable 7-43	LV743_HUMAN	3.62E−02	2.04
GN = IGLV7-43
VH6DJ protein (Fragment) GN = VH6DJ	A2N0T9_HUMAN	1.17E−03	2.03
Rheumatoid factor RF-IP24 (Fragment)	A2J1N4_HUMAN	4.03E−02	2.03
IGK@ protein GN = IGK@	Q6PIL8_HUMAN	1.03E−03	2.02
Immunoglobulin lambda variable 10-54	A0A1W2PQ80_HUMAN	2.28E−02	2.01
GN = IGLV10-54
cDNA FLJ90170 fis, clone	Q8NCL6_HUMAN	1.64E−02	2.00
MAMMA1000370, highly similar to
Ig alpha-1 chain C region
Myosin-reactive immunoglobulin heavy	Q9UL72_HUMAN	4.99E−03	1.98
chain variable region (Fragment)
Ankyrin-3 GN = ANK3	ANK3_HUMAN	1.48E−04	1.98
Plasma kallikrein (Fragment) GN = KLKB1	H0YAC1_HUMAN	9.99E−03	1.97
Collectin sub-family member 10 (C-type	A0A024R9J3_HUMAN	1.16E−03	1.97
lectin), isoform CRA_a GN = COLEC10
Anti-H1N1 influenza HA kappa chain	G3GAU4_HUMAN	3.84E−03	1.94
variable region (Fragment)
Myosin-reactive immunoglobulin light	Q9UL82_HUMAN	5.36E−03	1.93
chain variable region (Fragment)
cDNA FLJ14473 fis, clone	Q96K68_HUMAN	1.03E−02	1.93
MAMMA1001080, highly similar to Homo
sapiens SNC73 protein (SNC73) mRNA
Flotillin-1 (Fragment) GN = FLOT1	A0A140T9R1_HUMAN	5.26E−03	1.92
Immunoglobulin alpha-2 heavy chain	IGA2_HUMAN	7.29E−03	1.92
V1-3 protein (Fragment) GN = V1-3	Q5NV84_HUMAN	1.28E−02	1.91
Complement component C8 beta chain	F5GY80_HUMAN	4.87E−04	1.90
GN = C8B
cDNA FLJ78071, highly similar to Human	A8K8Z4_HUMAN	1.20E−02	1.89
MHC class III complement component
C6 mRNA
VH4 heavy chain variable region	O95973_HUMAN	1.67E−02	1.88
(Fragment) GN = IGM
Clusterin GN = CLU	CLUS_HUMAN	5.64E−05	1.86
Complement component C6 GN = C6	CO6_HUMAN	5.93E−03	1.84
Single-chain Fv (Fragment) GN = scFv	Q65ZC9_HUMAN	2.40E−02	1.84
Complement C3 GN = C3	CO3_HUMAN	5.33E−03	1.84
AT-rich interactive domain-containing	ARI5B_HUMAN	2.12E−02	1.84
protein 5B GN = ARID5B
Uncharacterized protein	Q7Z2U7_HUMAN	1.68E−02	1.84
Rheumatoid factor RF-ET11 (Fragment)	A2J1N8_HUMAN	1.02E−02	1.83
Hornerin GN = HRNR	HORN_HUMAN	1.37E−02	1.83
NADH-ubiquinone oxidoreductase chain 5	A0A059RS62_HUMAN	1.66E−03	1.82
GN = ND5
Immunogobulin kappa, VJ region	A2NH53_HUMAN	8.26E−03	1.81
(Fragment)
Complement component C8 alpha chain	CO8A_HUMAN	1.44E−02	1.79
GN = C8A
CYP20A1 protein (Fragment) GN = CYP20A1	Q567U3_HUMAN	5.40E−03	1.77
Collectin-11 GN = COLEC11	COL11_HUMAN	3.67E−02	1.76
V5-2 protein (Fragment) GN = V5-2	A2MYC8_HUMAN	4.46E−02	1.76
GCT-A3 heavy chain variable region	A0A0X9TD88_HUMAN	1.19E−03	1.76
(Fragment)
Cryocrystalglobulin CC2 lambda light	B1N7B9_HUMAN	7.22E−03	1.76
chain variable region (Fragment)
5′-nucleotidase, ecto (CD73) GN = NT5E	Q6NZX3_HUMAN	2.76E−02	1.75
IGL@ protein GN = IGL@	Q6PIK1_HUMAN	8.65E−03	1.73
Lectin galactoside-binding soluble 3	A0A0S2Z3Y1_HUMAN	1.67E−02	1.73
binding protein isoform 1 (Fragment)
GN = LGALS3BP
Fibrous sheath-interacting protein 2	FSIP2_HUMAN	7.32E−03	1.72
GN = FSIP2
Myosin-reactive immunoglobulin light	Q9UL70_HUMAN	4.24E−02	1.72
chain variable region (Fragment)
Immunoglobulin lambda variable 3-27	LV327_HUMAN	3.15E−02	1.68
GN = IGLV3-27
Fibrinogen alpha chain GN = FGA	FIBA_HUMAN	3.93E−03	1.67
Prolow-density lipoprotein receptor-	LRP1_HUMAN	1.33E−04	1.66
related protein 1 GN = LRP1
Immunglobulin heavy chain variable	Q0ZCI2_HUMAN	6.68E−03	1.64
region (Fragment)
Pregnancy zone protein GN = PZP	PZP_HUMAN	4.04E−02	1.63
cDNA FLJ75416, highly similar to Homo	A8K5T0_HUMAN	1.81E−02	1.62
sapiens complement factor H (CFH), mRNA
Heavy chain Fab (Fragment)	A2NYU8_HUMAN	1.12E−02	1.62
Apolipoprotein A-II GN = APOA2	APOA2_HUMAN	9.03E−04	1.61
Alpha-2-antiplasmin GN = SERPINF2	A2AP_HUMAN	4.66E−03	1.60
VH3 protein (Fragment) GN = VH3	Q9Y509_HUMAN	3.58E−02	1.60
Coagulation factor XIII B chain GN=F13B	F13B_HUMAN	2.28E−02	1.59
Cryocrystalglobulin CC1 kappa light chain	B1N7B8_HUMAN	4.54E−02	1.57
variable region (Fragment)
Complement C1s subcomponent GN = C1S	C1S_HUMAN	1.37E−03	1.57
Rheumatoid factor C6 light chain (Fragment)	A0N5G1_HUMAN	4.31E−02	1.57
GN = V-kappa-1
Hepatocyte growth factor activator	HGFA_HUMAN	2.18E−02	1.57
GN = HGFAC
Fibrinogen gamma chain, isoform CRA_a	D3DP16_HUMAN	3.23E−03	1.56
GN = FGG
Filaggrin-2 GN = FLG2	FILA2_HUMAN	1.29E−02	1.56
Immunoglobulin heavy variable 1-18	HV118_HUMAN	3.76E−02	1.55
GN = IGHV1-18
HRV Fab 026-VL (Fragment)	A2IPI5_HUMAN	4.02E−02	1.55
Protein Asterix (Fragment) GN = WDR83OS	M0R1D5_HUMAN	4.21E−02	1.55
IgG L chain	S6BAR0_HUMAN	2.68E−02	1.54
Anti-streptococcal/anti-myosin	Q96SB0_HUMAN	2.37E−02	1.54
immunoglobulin lambda light chain variable
region (Fragment)
Testicular tissue protein Li 70	A0A140VJJ6_HUMAN	1.10E−02	1.53
Uncharacterized protein	Q6MZQ6_HUMAN	2.19E−02	1.51
DKFZp686G11190
GN = DKFZp686G11190
F5-20 (Fragment) GN = F5-20	A0N7I9_HUMAN	2.19E−02	1.51
Uncharacterized protein	Q8NEJ1_HUMAN	4.33E−02	1.50
Uncharacterized protein	Q6DHW4_HUMAN	4.88E−02	1.45
NADH dehydrogenase [ubiquinone] 1	H7C2R1_HUMAN	1.89E−02	1.45
alpha subcomplex subunit 3 (Fragment)
GN = NDUFA3
Fibrinogen beta chain GN = FGB	FIBB_HUMAN	2.68E−02	1.43
IgG H chain	S6BGD4_HUMAN	3.88E−02	1.43
MS-F1 light chain variable region (Fragment)	A0A0X9V9B3_HUMAN	3.55E−02	1.43
Keratin, type II cytoskeletal 2 epidermal	K22E_HUMAN	1.57E−02	1.39
GN = KRT2
Protein S isoform 1 (Fragment) GN = PROS1	A0A0S2Z4K3_HUMAN	4.05E−02	1.30
Serine/threonine-protein kinase LMTK3	A0A0A0MQW5_HUMAN	2.45E−02	1.27
GN = LMTK3
Keratin, type I cytoskeletal 10 GN = KRT10	K1C10_HUMAN	2.66E−02	1.27

TABLE 4
Candidate corona protein biomarkers differentially expressed between
healthy controls and late stage ovarian carcinoma patients, as
identified by proteomic analysis of the ex vivo NP coronas.
Full list of proteins identified by Progenesis QI for
proteomics to be upregulated or downregulated in
late stage ovarian carcinoma patients in comparison with
healthy controls classified from the highest
max fold-change to the lowest. Only proteins with p < 0.05 are shown.
			Max
	Accession	Anova	fold
Identified Protein (n = 265)	Number	(p)	change
UPREGULATED (n = 73)
Keratin-associated protein	KR131_	3.93E−02	89.73
13-1 GN = KRTAP13-1	HUMAN
Keratin-associated protein 3-1	KRA31_	5.05E−03	41.13
GN = KRTAP3-1	HUMAN
Keratin, type II cuticular	KRT86_	4.96E−02	24.26
Hb6 GN = KRT86	HUMAN
Keratin, type II cuticular	KRT81_	4.16E−02	18.62
Hb1 GN = KRT81	HUMAN
Tubulin beta chain (Fragment)	Q6LC01_	2.66E−03	18.38
	HUMAN
Anion exchange protein	E2RVJ0_	1.36E−04	16.28
GN = SLC4A1	HUMAN
Coagulation factor XI GN = F11	FA11_	1.00E−06	15.01
	HUMAN
Tubulin beta-1 chain	TBB1_	7.14E−03	12.28
GN = TUBB1	HUMAN
Elongation factor	Q53GE9_	1.93E−03	11.65
1-alpha (Fragment)	HUMAN
Signal recognition particle	G3V4F7_	5.63E−03	11.07
54 kDa protein	HUMAN
GN = SRP54
Myosin-11 GN = MYH11	MYH11_	7.07E−04	9.62
	HUMAN
Zinc finger protein 621	C9JZC2_	4.13E−04	9.26
GN = ZNF621	HUMAN
Spectrin beta chain GN = SPTB	B2RMN7_	5.53E−05	9.05
	HUMAN
Tubulin alpha-1A chain	TBA1A_	7.54E−03	8.82
GN = TUBA1A	HUMAN
Serum amyloid A-1 protein	SAA1_	1.85E−03	7.32
GN = SAA1	HUMAN
Integrin alpha-6 GN = ITGA6	ITA6_	5.24E−03	7.31
	HUMAN
L-lactate dehydrogenase	LDHB_	1.43E−03	6.78
B chain GN = LDHB	HUMAN
Apolipoprotein C-III	B0YIW2_	9.73E−03	6.76
GN = APOC3	HUMAN
Actin, aortic smooth muscle	ACTA_	1.21E−03	6.54
GN = ACTA2	HUMAN
Apolipoprotein C-IV	APOC4_	1.73E−02	6.39
GN = APOC4	HUMAN
Ficolin-3 GN = FCN3	FCN3_	5.77E−04	6.36
	HUMAN
Actin, cytoplasmic 1 GN = ACTB	ACTB_	7.75E−04	6.12
	HUMAN
APOC4-APOC2 readthrough	K7ER74_	3.51E−03	5.97
(NMD candidate)	HUMAN
GN = APOC4-APOC2
Epididymis luminal protein	D0PNI1_	1.73E−02	5.89
4 GN = YWHAZ	HUMAN
Hemoglobin subunit beta	HBB_	1.89E−06	5.84
GN = HBB	HUMAN
Multimerin-1 GN = MMRN1	MMRN1_	1.78E−02	5.67
	HUMAN
Zinc finger CCCH-type	C9J6P4_	4.19E−03	5.65
antiviral protein 1	HUMAN
GN = ZC3HAV1
Spectrin alpha chain, erythrocytic	SPTA1_	8.77E−04	5.54
1 GN = SPTA1	HUMAN
Mutant hemoglobin alpha 2	A0A0K2BMD8_	5.14E−06	5.53
globin chain GN = HBA2	HUMAN
cDNA FLJ50805, highly	B7Z4C3_	3.11E−03	5.34
similar to Erythrocyte	HUMAN
membrane protein band 4.2
Solute carrier family 2	Q0P512_	6.29E−03	5.13
(Facilitated glucose	HUMAN
transporter), member 1
GN = SLC2A1
Aminopeptidase GN = ANPEP	A0A024RC61_	1.03E−02	5.07
	HUMAN
Ras-related protein Rab-1A	RAB1A_	1.41E−02	4.88
GN = RAB1A	HUMAN
cDNA FLJ77094, highly	A8K479_	2.68E−02	4.66
similar to Homo sapiens	HUMAN
apolipoprotein B (including
Ag(x) antigen) (APOB),
mRNA (Fragment)
RAP1B, member of RAS	A0A024RB87_	2.06E−02	4.63
oncogene family, isoform	HUMAN
CRA_a GN = RAP1B
Integrin beta-3 GN = ITGB3	ITB3_	1.46E−02	4.52
	HUMAN
Tenascin (Fragment) GN = TNC	H0YGZ3_	4.01E−03	4.21
	HUMAN
Filamin-A GN = FLNA	FLNA_	6.69E−03	4.20
	HUMAN
Catalase GN = CAT	CATA_	7.07E−05	4.06
	HUMAN
cDNA FLJ38781 fis, clone	B3KTV0_	1.54E−03	4.06
LIVER2000216, highly	HUMAN
similar to HEAT SHOCK
COGNATE 71 kDa
PROTEIN
Sushi, von Willebrand factor	SVEP1_	1.03E−02	3.99
type A, EGF and	HUMAN
pentraxin domain-containing
protein 1 GN = SVEP1
Reelin GN = RELN	RELN_	4.72E−03	3.87
	HUMAN
Integrin beta-1 GN = ITGB1	ITB1_	1.78E−02	3.63
	HUMAN
Apolipoprotein M GN = APOM	APOM_	1.66E−02	3.54
	HUMAN
CREB/ATF bZIP transcription	H0YDC7_	5.44E−03	3.49
factor (Fragment)	HUMAN
GN = CREBZF
Integrin alpha-IIb GN = ITGA2B	ITA2B_	4.51E−02	3.20
	HUMAN
Soluble scavenger receptor	SRCRL_	8.22E−03	3.17
cysteine-rich domain-	HUMAN
containing protein SSC5D
GN = SSC5D
Glyceraldehyde-3-phosphate	G3P_	8.07E−03	3.12
dehydrogenase	HUMAN
GN = GAPDH
Glycoprotein Ib (Platelet),	A0A0C4DGZ8_	2.57E−03	3.09
alpha polypeptide	HUMAN
GN = GP1BA
Coagulation factor XI	H0Y596_	1.46E−03	3.05
(Fragment) GN = F11	HUMAN
BTB/POZ domain-containing	KCTD5_	2.37E−02	3.00
protein KCTD5	HUMAN
GN = KCTD5
Peroxisomal bifunctional enzyme	ECHP_	1.23E−03	2.97
GN = EHHADH	HUMAN
FPGT-TNNI3K readthrough	V9GXZ4_	2.02E−02	2.71
GN = FPGT-TNNI3K	HUMAN
RUN and FYVE domain-	H0YD93_	5.51E−03	2.66
containing protein 2	HUMAN
(Fragment) GN = RUFY2
AP complex subunit beta	A0A087X253_	2.96E−02	2.63
GN = AP2B1	HUMAN
Ankyrin-1 GN = ANK1	ANK1_HUMAN	7.14E−03	2.56
Vinculin, isoform CRA_c	A0A024QZN4_	9.69E−03	2.56
GN = VCL	HUMAN
Moesin GN = MSN	MOES_HUMAN	2.87E−02	2.51
Keratin, type II cytoskeletal	K2C8_HUMAN	6.51E−04	2.44
8 GN = KRT8
Vascular endothelial growth	VGFR3_	4.16E−03	2.40
factor receptor 3	HUMAN
GN = FLT4
Proteoglycan 4, isoform	A0A024R930_	1.21E−02	2.32
CRA_a GN = PRG4	HUMAN
Neutral alpha-glucosidase	GANAB_	1.42E−02	2.28
AB GN = GANAB	HUMAN
Fructose-bisphosphate aldolase	ALDOA_	1.73E−02	2.17
A GN = ALDOA	HUMAN
Apolipoprotein F GN = APOF	APOF_HUMAN	1.18E−02	2.16
Platelet-activating factor	A0A024RD39_	2.78E−03	2.10
acetylhydrolase	HUMAN
GN = PLA2G7
Bcl-2-associated transcription	A0A1W2PQ43_	4.53E−02	2.00
factor 1 GN = BCLAF1	HUMAN
Histone-lysine N-	KMT2D_	1.91E−02	1.98
methyltransferase	HUMAN
2D GN = KMT2D
Fatty acid desaturase	A0A087WU67_	1.28E−02	1.92
6 GN = FADS6	HUMAN
cAMP-responsive element	H7C4X0_	1.13E−02	1.89
modulator (Fragment)	HUMAN
GN = CREM
Tenascin-X GN = TNXB	A0A087X010_	1.09E−02	1.89
	HUMAN
Zinc finger protein 687	H0Y5I5_	2.03E−02	1.84
(Fragment) GN = ZNF687	HUMAN
Apolipoprotein B (Including	C0JYY2_	1.93E−02	1.82
Ag(X) antigen)	HUMAN
GN = APOB
Actinin alpha 4 isoform 3	A0A0S2Z3C0_	3.85E−02	1.74
(Fragment) GN = ACTN4	HUMAN
DOWNREGULATED (n = 192)
Regucalcin GN = RGN	RGN_HUMAN	7.89E−03	177.77
Beta-Ala-His dipeptidase	CNDP1_	9.48E−09	18.28
GN = CNDP1	HUMAN
E3 ubiquitin-protein ligase	TRI56_HUMAN	8.61E−03	7.94
TRIM56 GN = TRIM56
Immunoglobulin kappa	KVD13_	1.56E−02	7.57
variable 1D-13	HUMAN
GN = IGKV1D-13
Immunoglobulin lambda variable	LV39_	1.32E−02	7.02
3-9 GN = IGLV3-9	HUMAN
IgG H chain	S6AWF0_	1.72E−02	5.57
	HUMAN
Phosphatidylinositol-glycan-	PHLD_	1.47E−08	5.44
specific phospholipase	HUMAN
D GN = GPLD1
Immunoglobulin heavy variable	HVD82_	2.43E−02	5.38
4-38-2 GN = IGHV4-38-2	HUMAN
Rheumatoid factor RF-IP24	A2J1N4_	2.57E−03	5.27
(Fragment)	HUMAN
Immunoglobulin kappa	KVD21_	2.30E−04	4.66
variable 6D-21	HUMAN
GN = IGKV6D-21
cDNA, FLJ93914, highly	B2R8I2_	1.30E−04	4.63
similar to Homo sapiens	HUMAN
histidine-rich glycoprotein
(HRG), mRNA
Histidine-rich glycoprotein	HRG_HUMAN	1.30E−04	4.63
GN = HRG
VH6DJ protein (Fragment)	A2N0U0_	1.73E−02	4.56
GN = VH6DJ	HUMAN
Uncharacterized protein	Q6N095_	2.49E−02	4.26
GN = DKFZp686K03196	HUMAN
Myosin-reactive immunoglobulin	Q9UL90_	7.27E−03	4.14
heavy chain	HUMAN
variable region (Fragment)
C4B (Fragment) GN = C4B	Q6U2L6_	1.39E−03	3.84
	HUMAN
IGK@ protein GN = IGK@	Q6PIL8_	4.55E−05	3.68
	HUMAN
GCT-A8 light chain variable	A0A109PS54_	2.90E−03	3.66
region (Fragment)	HUMAN
Selenoprotein P (Fragment)	A0A182DWH7_	3.12E−06	3.63
GN = SELENOP	HUMAN
MS-A6 heavy chain variable	A0A0X9USK2_	8.63E−03	3.63
region (Fragment)	HUMAN
Precursor (AA −19 to 108)	A2NV54_	5.20E−03	3.40
(Fragment)	HUMAN
Serpin peptidase inhibitor,	A0A024R6N9_	5.20E−05	3.40
clade A (Alpha-1	HUMAN
antiproteinase, antitrypsin),
member 5, isoform
CRA_a GN = SERPINA5
Heavy chain Fab (Fragment)	A2NYV1_	4.24E−04	3.24
	HUMAN
Immunoglobulin lambda variable	LV327_	3.04E−04	3.18
3-27 GN = IGLV3-27	HUMAN
Plasminogen GN = PLG	PLMN_HUMAN	2.37E−02	3.17
UBX domain-containing	A0A087WWA4_	2.12E−02	3.17
protein 8 (Fragment)	HUMAN
GN = UBXN8
V5-6 protein (Fragment)	Q5NV92_	4.97E−02	3.17
GN = V5-6	HUMAN
Myosin-reactive immunoglobulin	Q9UL82_	8.13E−04	3.13
light chain variable	HUMAN
region (Fragment)
Serine/threonine-protein	A0A0A0MQW5_	2.56E−03	3.12
kinase LMTK3	HUMAN
GN = LMTK3
Immunoglobulin kappa	KVD20_	1.68E−02	3.06
variable 3D-20	HUMAN
GN = IGKV3D-20
IGK@ protein GN = IGK@	Q6P5S8_	1.26E−04	3.05
	HUMAN
Single-chain Fv (Fragment)	Q65ZC9_	3.26E−03	2.99
GN = scFv	HUMAN
Immunoglobulin heavy variable	HV343_	2.39E−03	2.98
3-43 GN = IGHV3-43	HUMAN
FLJ00382 protein (Fragment)	Q8NF20_	1.46E−02	2.98
GN = FLJ00382	HUMAN
Immunoglobulin delta heavy chain	IGD_HUMAN	1.46E−02	2.98
Myosin-reactive immunoglobulin	Q9UL72_	5.86E−03	2.96
heavy chain	HUMAN
variable region (Fragment)
Anti-H1N1 influenza HA kappa	G3GAU4_	8.46E−04	2.94
chain variable	HUMAN
region (Fragment)
Coagulation factor XII GN = F12	A0A0R7FJH5_	1.15E−02	2.94
	HUMAN
Transthyretin GN = TTR	A0A087WV45_	1.14E−04	2.92
	HUMAN
Serpin peptidase inhibitor,	A0A024R944_	2.06E−02	2.92
clade C (Antithrombin),	HUMAN
member 1, isoform CRA_a
GN = SERPINC1
Angiotensinogen variant	Q53GY3_	3.13E−03	2.91
(Fragment)	HUMAN
Heavy chain Fab (Fragment)	A2NYU9_	1.63E−02	2.90
	HUMAN
Ig heavy chain variable	A0A068LRW6_	1.04E−02	2.89
region (Fragment)	HUMAN
Vitronectin GN = VTN	VTNC_HUMAN	1.44E−07	2.87
A30 (Fragment)	A2MYE1_	5.80E−04	2.86
	HUMAN
Plasma kallikrein (Fragment)	H0YAC1_	2.91E−03	2.84
GN = KLKB1	HUMAN
Polymeric immunoglobulin	PIGR_HUMAN	7.22E−03	2.84
receptor GN = PIGR
Anoctamin (Fragment)	H7C220_	9.13E−05	2.84
GN = ANO7 PE = 3 SV = 8	HUMAN
Apolipoprotein A-IV	APOA4_	1.91E−03	2.82
GN = APOA4	HUMAN
IBM-B2 light chain variable	A0A0X9V9D6_	4.26E−02	2.81
region (Fragment)	HUMAN
VH6DJ protein (Fragment)	A2N0T9_	5.30E−05	2.76
GN = VH6DJ	HUMAN
Immunoglobulin heavy variable	HV349_	6.07E−04	2.76
3-49 GN = IGHV3-49	HUMAN
Immunoglobulin lambda variable	LV746_	1.97E−03	2.73
7-46 GN = IGLV7-46	HUMAN
V1-2 protein (Fragment)	A2MYD6_	7.99E−03	2.70
GN = V1-2	HUMAN
MS-A1 light chain variable	A0A109PSY4_	1.81E−02	2.69
region (Fragment)	HUMAN
Ig heavy chain variable	A0A068LKQ2_	1.70E−04	2.68
region (Fragment)	HUMAN
Uncharacterized protein	Q6MZL2_	1.03E−04	2.68
DKFZp686M0562	HUMAN
(Fragment) GN =
DKFZp686M0562
N-acetylmuramoyl-L-	PGRP2_	5.74E−05	2.65
alanine amidase	HUMAN
GN = PGLYRP2
CYP20A1 protein (Fragment)	Q567U3_	2.44E−03	2.65
GN = CYP20A1	HUMAN
Ankyrin-3 GN = ANK3	ANK3_HUMAN	1.48E−05	2.63
Uncharacterized protein	Q8NEJ1_	3.94E−03	2.60
	HUMAN
V5-2 protein (Fragment)	A2MYC8_	2.05E−02	2.59
GN = V5-2	HUMAN
Uncharacterized protein	Q6DHW4_	1.29E−03	2.57
	HUMAN
N90-VRC38.04 heavy chain	A0A1W6IYI9_	5.52E−03	2.57
variable region	HUMAN
(Fragment)
Epididymis luminal protein	V9HW34_	3.38E−04	2.56
213 GN = HEL-213	HUMAN
IGK@ protein GN = IGK@	Q6PJF2_	5.55E−03	2.54
	HUMAN
Serum paraoxonase/arylesterase	PON1_HUMAN	1.52E−05	2.50
1 GN = PON1
MS-D1 light chain variable	A0A0X9TD47_	7.08E−03	2.49
region (Fragment)	HUMAN
Fibrinogen alpha chain GN = FGA	FIBA_HUMAN	9.80E−05	2.48
K light chain variable	A2NXP9_	6.04E−03	2.46
region (Fragment)	HUMAN
Immunoglobulin lambda variable	LV743_	3.50E−02	2.46
7-43 GN = IGLV7-43	HUMAN
Immunoglobulin alpha-2	IGA2_HUMAN	8.22E−03	2.44
heavy chain
Myosin-reactive immunoglobulin	Q9UL86_	5.33E−03	2.42
kappa chain	HUMAN
variable region (Fragment)
Rho GTPase-activating protein	A0A087WXU2_	5.48E−04	2.42
23 (Fragment)	HUMAN
GN = ARHGAP23
Alpha-1-antitrypsin GN =	A1AT_HUMAN	1.90E−02	2.41
SERPINA1
Alpha-1-antitrypsin GN =	A0A024R6I7_	1.90E−02	2.41
SERPINA1	HUMAN
Burkitt's lymphoma	A0N2N3_	2.90E−02	2.40
translocation t(2;8) encoding	HUMAN
kappa light chain,. Chromosome
8q+ break point
(Fragment)
cDNA FLJ59854, highly	B4DEU0_	1.04E−03	2.40
similar to Homo sapiens	HUMAN
pitrilysin metallopeptidase
1 (PITRM1), mRNA
Immunoglobulin heavy variable	HV70D_	1.75E−02	2.39
2-70D GN = IGHV2-70D	HUMAN
IgG H chain	S6BGD4_	5.12E−04	2.39
	HUMAN
Coagulation factor XIII	F13B_HUMAN	9.07E−04	2.39
B chain GN = F13B
Mannan-binding lectin	MASP1_	1.31E−03	2.37
serine protease 1	HUMAN
GN = MASP1
Fibrinogen gamma chain,	D3DP16_	4.09E−05	2.37
isoform CRA_a GN = FGG	HUMAN
Immunoglobulin heavy variable	HV313_	1.54E−02	2.36
3-13 GN = IGHV3-13	HUMAN
Alternative protein NIPA2	L8E8V4_	2.45E−03	2.35
GN = NIPA2	HUMAN
MS-F1 light chain variable	A0A0X9V9B3_	5.83E−04	2.34
region (Fragment)	HUMAN
Anti-streptococcal/anti-myosin	Q96SB0_	1.91E−03	2.34
immunoglobulin	HUMAN
lambda light chain variable
region (Fragment)
IBM-A3 heavy chain	A0A0X9UWM4_	1.96E−02	2.33
variable region (Fragment)	HUMAN
VH4 heavy chain variable	O95973_	7.83E−03	2.28
region (Fragment)	HUMAN
GN = IGM
Immunoglobulin heavy variable	HV205_HUMAN	9.89E−03	2.27
2-5 GN = IGHV2-5
Uncharacterized protein	Q7Z2U7_	5.54E−03	2.27
	HUMAN
REV25-2 (Fragment)	A0N7J6_	1.23E−02	2.26
	HUMAN
V2-17 protein (Fragment)	Q5NV90_	4.27E−02	2.25
GN = V2-17	HUMAN
Intestinal mucin (Fragment)	O43419_	2.39E−03	2.24
GN = MUC3	HUMAN
Hepatocyte growth factor	HGFA_HUMAN	6.86E−03	2.23
activator GN = HGFAC
Rheumatoid factor	A2J1N6_	2.55E−03	2.22
RF-ET9 (Fragment)	HUMAN
Rheumatoid factor C6	A0N5G1_	2.53E−03	2.21
light chain (Fragment)	HUMAN
GN = V-kappa-1
Cryocrystalglobulin CC1	B1N7B8_	5.36E−03	2.20
kappa light chain variable	HUMAN
region (Fragment)
Testicular tissue protein Li 70	A0A140VJJ6_	3.70E−04	2.20
	HUMAN
Uncharacterized	A0A0G2JRQ6_	1.00E−02	2.20
protein (Fragment)	HUMAN
Complement component C8	CO8G_	1.57E−02	2.17
gamma chain	HUMAN
GN = C8G
Cold agglutinin FS-2	A2NB46_	3.57E−02	2.15
L-chain (Fragment)	HUMAN
Immunogobulin kappa,	A2NH53_	1.23E−02	2.14
VJ region (Fragment)	HUMAN
Rheumatoid factor	A2J1M8_	1.45E−02	2.14
RF-IP12 (Fragment)	HUMAN
Rheumatoid factor light chain	A2NW98_	2.50E−02	2.13
variable region	HUMAN
(Fragment)
Anti-staphylococcal enterotoxin	A0A1L2BU33_	6.80E−03	2.13
D heavy chain	HUMAN
variable region (Fragment)
Cryocrystalglobulin CC2 lambda	B1N7B9_	1.20E−02	2.13
light chain variable	HUMAN
region (Fragment)
Immunoglobulin heavy variable	HV118_	3.98E−03	2.12
1-18 GN = IGHV1-18	HUMAN
Complement component C7	CO7_HUMAN	1.65E−02	2.11
GN = C7
N90-VRC38.09 heavy chain	A0A1W6IYJ1_	5.68E−03	2.10
variable region	HUMAN
(Fragment)
Immunoglobulin heavy variable	HV373_	3.00E−02	2.09
3-73 GN = IGHV3-73	HUMAN
VH3 protein (Fragment)	Q9Y509_	9.22E−03	2.09
GN = VH3	HUMAN
Prolow-density lipoprotein	LRP1_	3.34E−04	2.08
receptor-related protein	HUMAN
1 GN = LRP1
Fibrous sheath-interacting	FSIP2_	5.33E−03	2.08
protein 2 GN = FSIP2	HUMAN
Immunoglobulin kappa variable	KV401_	6.46E−03	2.08
4-1 GN = IGKV4-1	HUMAN
AT-rich interactive domain-	ARI5B_	1.29E−02	2.07
containing protein 5B	HUMAN
GN = ARID5B
Immunglobulin heavy chain	Q0ZCJ1_	2.81E−02	2.06
variable region	HUMAN
(Fragment)
MS-D4 heavy chain variable	A0A0X9UWK7_	1.23E−02	2.06
region (Fragment)	HUMAN
Complement C3 GN = C3	CO3_HUMAN	6.46E−03	2.05
Myosin-reactive immunoglobulin	Q9UL88_	1.87E−03	2.05
heavy chain	HUMAN
variable region (Fragment)
Uncharacterized protein	Q6MZQ6_	2.51E−03	2.05
DKFZp686G11190	HUMAN
GN = DKFZp686G11190
F5-20 (Fragment) GN = F5-20	A0N7I9_	2.51E−03	2.05
	HUMAN
Immunglobulin heavy chain	Q0ZCI2_	2.01E−03	2.05
variable region	HUMAN
(Fragment)
Immunoglobulin heavy variable	HV374_	1.61E−02	2.05
3-74 GN = IGHV3-74	HUMAN
GCT-A3 heavy chain variable	A0A0X9TD88_	1.04E−04	2.04
region (Fragment)	HUMAN
Fibrinogen beta chain GN = FGB	FIBB_HUMAN	7.65E−04	2.03
Immunoglobulin heavy	A0A0C4DH35_	1.76E−03	2.01
variable 3-35 (non-	HUMAN
functional) (Fragment)
GN = IGHV3-35
IBM-B2 heavy chain variable	A0A125QYY9_	9.94E−03	2.00
region (Fragment)	HUMAN
Lectin galactoside-binding	A0A0S2Z3Y1_	1.29E−02	1.98
soluble 3 binding protein	HUMAN
isoform 1 (Fragment)
GN = LGALS3BP
Collectin sub-family member	A0A024R9J3_	1.32E−02	1.97
10 (C-type lectin),	HUMAN
isoform CRA_a GN = COLEC10
Cortactin, isoform CRA_c	A0A024R5M3_	2.05E−02	1.97
GN = CTTN	HUMAN
GCT-A5 heavy chain variable	A0A0X9T0H6_	2.06E−02	1.97
region (Fragment)	HUMAN
Complement factor properdin	A0A0S2Z4I5_	1.80E−03	1.96
isoform 1 (Fragment)	HUMAN
GN = CFP
Immunoglobulin kappa light chain	IGK_HUMAN	1.66E−03	1.96
Cadherin EGF LAG	CELR2_	1.18E−03	1.95
seven-pass G-type receptor 2	HUMAN
GN = CELSR2
Alpha-2-antiplasmin	A2AP_HUMAN	4.94E−04	1.95
GN = SERPINF2
IBM-A1 heavy chain variable	A0A120HF66_	1.34E−02	1.94
region (Fragment)	HUMAN
Immunoglobulin kappa variable	KV621_	2.73E−02	1.93
6-21 GN = IGKV6-21	HUMAN
Probable ATP-dependent	A0A0C4DG89_	7.92E−04	1.93
RNA helicase DDX46	HUMAN
GN = DDX46
Immunglobulin heavy	Q0ZCH9_	3.29E−02	1.92
chain variable region	HUMAN
(Fragment)
Immunoglobulin heavy variable	HV372_	7.24E−03	1.92
3-72 GN = IGHV3-72	HUMAN
MS-C1 heavy chain variable	A0A125U0U7_	2.10E−02	1.91
region (Fragment)	HUMAN
Clusterin GN = CLU	CLUS_HUMAN	6.49E−05	1.91
Immunoglobulin J chain	IGJ_HUMAN	1.89E−03	1.90
GN = JCHAIN
Complement component	CO8A_HUMAN	1.88E−02	1.88
C8 alpha chain GN = C8A
Immunoglobulin kappa	KVD29_	1.26E−02	1.87
variable 2D-29	HUMAN
GN = IGKV2D-29
N90-VRC38.10 heavy	A0A1W6IYI8_	3.33E−02	1.86
chain variable region	HUMAN
(Fragment)
Microfibrillar protein	Q9NP29_	1.01E−02	1.86
2 (Fragment)	HUMAN
Myosin-reactive	Q9UL70_	4.49E−02	1.85
immunoglobulin light	HUMAN
chain variable region (Fragment)
NADH dehydrogenase	H7C2R1_	5.40E−03	1.85
[ubiquinone] 1 alpha	HUMAN
subcomplex subunit 3 (Fragment)
GN = NDUFA3
N90-VRC38.08 heavy chain	A0A1W6IYI5_	1.22E−02	1.83
variable region	HUMAN
(Fragment)
Immunoglobulin heavy variable	HV64D_	2.66E−02	1.81
3-64D GN = IGHV3-64D	HUMAN
Complement C1s	C1S_HUMAN	1.31E−03	1.81
subcomponent GN = C1S
Calcium-binding mitochondrial	CMC1_	4.45E−02	1.79
carrier protein	HUMAN
Aralar1 GN = SLC25A12
V1-3 protein (Fragment)	Q5NV84_	3.07E−02	1.76
GN = V1-3	HUMAN
GCT-A6 heavy chain	A0A109PVK5_	2.08E−02	1.76
variable region (Fragment)	HUMAN
Microsomal triglyceride	MTP_	2.31E−02	1.75
transfer protein large	HUMAN
subunit GN = MTTP
cDNA FLJ75416, highly	A8K5T0_	7.49E−03	1.75
similar to Homo sapiens	HUMAN
complement factor H
(CFH), mRNA
Protein Asterix (Fragment)	M0R1D5_	1.42E−02	1.75
GN = WDR83OS	HUMAN
V1-13 protein (Fragment)	Q5NV69_	2.77E−02	1.74
GN = V1-13	HUMAN
Caveolae-associated protein 2	CAVN2_	2.00E−03	1.74
GN = CAVIN2	HUMAN
Serine palmitoyltransferase,	A0A024R6H1_	7.42E−03	1.74
long chain base	HUMAN
subunit 2, isoform CRA_a
GN = SPTLC2
Fibulin-1 GN = FBLN1	B1AHL2_	2.13E−02	1.73
	HUMAN
Immunoglobulin heavy constant	IGHM_HUMAN	6.00E−03	1.73
mu GN = IGHM
Complement component 1, q	A0A024RAB9_	5.54E−03	1.73
subcomponent, B	HUMAN
chain, isoform CRA_a
GN = C1QB
Immunoglobulin lambda variable	LV319_	2.60E−02	1.73
3-19 GN = IGLV3-19	HUMAN
NADH-ubiquinone	A0A059RS62_	1.18E−02	1.72
oxidoreductase chain 5	HUMAN
GN = ND5
Immunoglobulin kappa variable	KV228_	1.31E−02	1.69
2-28 GN = IGKV2-28	HUMAN
Pregnancy zone protein GN = PZP	PZP_HUMAN	4.26E−02	1.68
Immunoglobulin heavy	Q9NPP6_	3.54E−02	1.67
chain variant (Fragment)	HUMAN
Cold agglutinin FS-1	A2NB45_	1.70E−02	1.66
L-chain (Fragment)	HUMAN
V1-16 protein (Fragment)	Q5NV81_	4.45E−02	1.65
GN = V1-16	HUMAN
Myosin-reactive immunoglobulin	Q9UL73_	3.07E−02	1.64
heavy chain	HUMAN
variable region (Fragment)
Complement component 1,	A0A024RAA7_	7.94E−03	1.64
q subcomponent, C	HUMAN
chain, isoform CRA_a
GN = C1QC
IGL@ protein GN = IGL@	Q6PIK1_	1.43E−02	1.63
	HUMAN
Protein S isoform 1	A0A0S2Z4K3_	1.25E−03	1.62
(Fragment) GN = PROS1	HUMAN
Alpha-2-macroglobulin	A2MG_	4.77E−02	1.59
GN = A2M	HUMAN
Cryocrystalglobulin CC1	B1N7B6_	4.29E−03	1.58
heavy chain variable	HUMAN
region (Fragment)
Complement component	F5GY80_	2.03E−02	1.58
C8 beta chain GN = C8B	HUMAN
Ubiquitinyl hydrolase 1	A0A024R8A9_	3.55E−02	1.57
GN = USP20	HUMAN
Coagulation factor XIII A	F13A_	3.58E−02	1.56
chain GN = F13A1	HUMAN
Full-length cDNA clone	Q86TT1_	1.95E−02	1.55
CS0DD006YL02 of	HUMAN
Neuroblastoma of
Homo sapiens (human)
CD5 antigen-like GN = CD5L	CD5L_	1.23E−02	1.54
	HUMAN
C4b-binding protein beta chain	C4BPB_	4.39E−04	1.51
GN = C4BPB	HUMAN
Complement component C6	CO6_	4.34E−02	1.51
GN = C6	HUMAN
IgG L chain	S6BAR0_	2.75E−02	1.49
	HUMAN
Apolipoprotein A-I, isoform	A0A024R3E3_	3.80E−02	1.49
CRA_a GN = APOA1	HUMAN
cDNA FLJ60320, highly	B4DPS0_	3.93E−02	1.48
similar to Tyrosine-protein	HUMAN
phosphatase non-receptor
type6 (EC 3.1.3.48)	C4BPA_
C4b-binding protein alpha	HUMAN	1.30E−03	1.46
chain GN = C4BPA
cDNA FLJ51597, highly	B4E1D8_	1.30E−03	1.46
similar to C4b-binding	HUMAN
protein alpha chain
Integrator complex subunit 4	INT4_	3.39E−02	1.41
GN = INTS4	HUMAN
Complement component 1,	A0A024RAG6_	1.72E−02	1.37
q subcomponent, A	HUMAN
chain, isoform CRA_a
GN = C1QA

TABLE 5
Candidate corona protein biomarkers differentially expressed between
early and late stage ovarian carcinoma patients, as
identified by proteomic analysis of the ex vivo NP coronas.
Full list of proteins identified by Progenesis QI for
proteomics to be upregulated or downregulated in
late stage ovarian carcinoma patients in comparison
with early stage ovarian carcinoma patients
classified from the highest max fold-change
to the lowest. Only proteins with p < 0.05 are shown.
			Max
	Accession	Anova	fold
Identified Protein (n = 50)	Number	(p)	change
UPREGULATED (n = 25)
Keratin-associated protein 9-2	A0A140TA58_	4.72E−02	Infinity
GN = KRTAP9-2	HUMAN
Keratin associated protein	Q3LI55_	4.47E−02	1596.12
GN = KRTAP11-1	HUMAN
Keratin-associated protein 13-1	KR131_	4.08E−02	55.16
GN = KRTAP13-1	HUMAN
Keratin-associated protein 3-1	KRA31_	3.29E−03	23.28
GN = KRTAP3-1	HUMAN
Keratin, type II cuticular Hb6	KRT86_	4.65E−03	22.92
GN = KRT86	HUMAN
Keratin, type II cuticular Hb1	KRT81	6.11E−03	16.36
GN = KRT81	HUMAN
HLA class I histocompatibility	1B57_	1.92E−02	11.43
antigen, B-57
alpha chain GN = HLA-B	HUMAN
Flotillin-1 (Fragment)	A0A140T9R1_	2.55E−04	10.74
GN = FLOT1	HUMAN
cDNA FLJ43122 fis, clone	B3KWI4_	3.02E−02	4.09
CTONG3003737,	HUMAN
highly similar to Leucine-rich
repeat-containing
protein 15
Zinc finger CCCH-type	C9J6P4_	5.57E−03	3.95
antiviral protein 1	HUMAN
GN = ZC3HAV1
Zinc finger protein 621	C9JZC2_	2.11E−02	3.21
GN = ZNF621	HUMAN
Coagulation factor XI GN = F11	FA11_	5.30E−03	2.97
	HUMAN
Coagulation factor	H0Y596_	3.42E−03	2.21
XI (Fragment)	HUMAN
GN = F11
Vinculin, isoform CRA_c	A0A024QZN4_	6.53E−03	2.18
GN = VCL	HUMAN
CREB/ATF bZIP	H0YDC7_	1.55E−02	2.09
transcription factor	HUMAN
(Fragment) GN = CREBZF
Soluble scavenger receptor	SRCRL_	2.54E−02	2.07
cysteine-rich	HUMAN
domain-containing protein
SSC5D GN = SSC5D
FPGT-TNNI3K readthrough	V9GXZ4_	2.59E−02	1.92
GN = FPGT-TNNI3K	HUMAN
Fructose-bisphosphate aldolase	ALDOA_	1.65E−02	1.90
A GN = ALDOA	HUMAN
RUN and FYVE	H0YD93_	2.09E−02	1.87
domain-containing protein 2	HUMAN
(Fragment) GN = RUFY2
Pescadillo homolog GN = PES1	PESC_	3.07E−02	1.76
	HUMAN
Proteoglycan 4, isoform	A0A024R930_	4.16E−02	1.76
CRA_a GN = PRG4	HUMAN
Neutral alpha-glucosidase AB	GANAB_	4.74E−02	1.75
GN = GANAB	HUMAN
PH-interacting protein	PHIP_	2.80E−02	1.70
GN = PHIP	HUMAN
Histone-lysine	KMT2D_	2.63E−02	1.69
N-methyltransferase 2D	HUMAN
GN = KMT2D
Zinc finger protein 687 (Fragment)	H0Y5I5_	2.19E−02	1.63
GN = ZNF687	HUMAN
DOWNREGULATED (n = 25)
Histone H2A GN =	A0A024R017_	1.89E−02	10.35
HIST1H2AC	HUMAN
POTE ankyrin domain	POTEJ_	1.36E−02	7.42
family member J	HUMAN
GN = POTEJ
Histone H2B type 1-B	H2B1B_	2.19E−02	5.28
GN = HIST1H2BB	HUMAN
Immunoglobulin heavy	HV226_	2.67E−02	4.58
variable 2-26	HUMAN
GN = IGHV2-26
Immunoglobulin heavy	A0A075B7B8_	5.68E−03	2.72
variable 3/OR16-12	HUMAN
(non-functional) (Fragment)
GN = IGHV3OR16-12
Cortactin, isoform CRA_c	A0A024R5M3_	4.85E−02	2.50
GN = CTTN	HUMAN
MS-D1 light chain variable	A0A0X9TD47_	5.37E−03	2.30
region (Fragment)	HUMAN
Heavy chain Fab (Fragment)	A2NYU9_	3.48E−02	2.13
	HUMAN
Anti-staphylococcal enterotoxin	A0A1L2BU33_	1.72E−02	2.13
D heavy chain	HUMAN
variable region (Fragment)
Polymeric immunoglobulin	PIGR_	2.14E−04	2.04
receptor GN = PIGR	HUMAN
Immunoglobulin	HV102_	2.26E−02	2.03
heavy variable 1-2	HUMAN
GN = IGHV1-2
Myosin-reactive	Q9UL88_	2.14E−02	1.99
immunoglobulin	HUMAN
heavy chain
variable region (Fragment)
Myosin-reactive	Q9UL86_	1.80E−02	1.99
immunoglobulin	HUMAN
kappa chain
variable region (Fragment)
Immunoglobulin heavy variable	HV349_	1.57E−02	1.96
3-49	HUMAN
GN = IGHV3-49
N90-VRC38.08 heavy	A0A1W6IYI5_	1.53E−02	1.85
chain variable region	HUMAN
(Fragment)
IGK@ protein GN = IGK@	Q6PIL8_	4.05E−02	1.82
	HUMAN
Immunoglobulin heavy variable	A0A0C4DH35_	3.52E−02	1.79
3-35 (non-	HUMAN
functional) (Fragment)
GN = IGHV3-35
Uncharacterized protein	Q8NEJ1_	3.62E−02	1.74
	HUMAN
Alpha-2-macroglobulin	A2MG_	2.19E−02	1.68
GN = A2M	HUMAN
IgG H chain	S6BGD4_	2.55E−02	1.67
	HUMAN
MS-F1 light chain variable	A0A0X9V9B3_	3.92E−02	1.64
region (Fragment)	HUMAN
Phosphatidylinositol-	PHLD_	2.54E−02	1.59
glycan-specific	HUMAN
phospholipase D GN = GPLD1
Fibrinogen gamma chain,	D3DP16_	2.62E−02	1.52
isoform CRA_a	HUMAN
GN = FGG
Cryocrystalglobulin CC1	B1N7B6_	1.29E−02	1.52
heavy chain variable	HUMAN
region (Fragment)
Angiotensinogen	Q53GY3_	1.94E−02	1.39
variant (Fragment)	HUMAN

TABLE 6
Mass Spectrometry-based lipidomic analysis.
List of all complex lipids identified in healthy human plasma and
onto the surface of HSPC:CHOL liposomes,
as these were found by LC-MS/MS. All samples were run in
both positive and negative mode. Raw abundance
values are shown below for all complex lipids identified.
							Corona-
					Bare	Corona-	coated
		RT	lipid	Bare	NPs +	coated	NPs +
Compound	m/z	(min)	cocktail	NPs	STD	NPs	STD
CE 16:0	647.57	1.19	1	2	2	15	18
CE 18:0	675.60	1.20	0	0	0	23	21
CE 18:2	671.58	1.17	0	0	1	593	584
CE 18:3	669.56	1.19	0	0	1	17	13
CE 20:4	695.58	1.21	6	1	3	328	291
CE 20:5	693.56	1.23	0	0	0	7	9
CE 22:5	721.58	1.37	3	944	340	595	752
CE 22:6	719.58	1.25	0	9	4	88	106
CE std	635.50	1.38	14	199	92	116	92
DG 31:0	572.44	1.79	0	109	206	124	89
DG 33:0	600.37	1.46	0	4	6	2	2
DG 34:0	614.49	1.75	2	5	7	7	8
DG 34:4	606.62	1.72	0	0	1	8	17
DG 34:5	604.54	1.43	153	0	101	121	257
DG 35:0	628.51	1.54	0	39	46	26	32
DG 36:2	638.57	1.68	0	13	26	13	0
DG 36:3	636.56	1.50	1	1	8	16	33
DG 36:4	634.54	1.52	0	0	0	5	10
DG 38:1	668.53	1.54	1	0	0	13	26
DG 38:5	660.56	1.68	0	54	54	54	8
DG 39:4	676.53	1.69	0	14	20	15	2
DG 41:5	702.50	1.94	3	287	258	293	252
DG 44:0	754.45	1.42	3	0	3	0	1
DG 44:4	746.55	1.48	13	0	9	0	7
DG std	643.60	1.42	1408	0	872	176	781
STD without H2O	608.57	1.42	141589	129	106962	83	86217
LPC 14:0	468.31	4.45	1	1	0	15	30
LPC 15:0	482.35	4.40	2	1	1	242	419
LPC 16:0	496.34	4.44	2	1923	2362	18924	31271
LPC 16:1	494.32	4.47	1	0	0	6	29
LPC 17:0	510.36	4.42	2	27	24	476	772
LPC 18:0	524.37	4.43	0	23846	29397	28888	44533
LPC 18:2	520.34	4.50	0	1	3	391	1116
LPC 18:3	518.32	4.44	0	220	341	2210	3613
LPC 19:0	538.39	4.41	0	2	3	35	59
LPC 20:0	552.40	4.41	0	49	60	58	91
LPC 20:1	550.39	4.45	0	0	0	18	52
LPC 20:2	548.51	4.42	3	0	17	0	5
LPC 20:3	546.35	4.43	3	3033	4423	3698	5602
LPC 20:5	542.32	4.50	0	0	0	27	152
LPC 22:3	574.35	4.73	0	7	3	0	1
LPC 22:4	572.37	4.54	0	1	0	1	8
LPC 22:6	568.33	4.42	3	24	30	21	22
LPC std	640.52	4.38	3395	1	3041	1	3066
PC 28:0	678.51	3.82	2	2	2	4	5
PC 30:1	704.53	3.86	0	0	2	4	5
PC 30:0	706.54	3.82	2	1	1	150	187
PC 32:1p/PC 32:2e	716.56	3.86	1	0	0	1	5
PC 32:0p/PC 32:1e	718.58	3.83	2	0	1	122	180
PC 32:0e	720.59	3.78	1	4	4	377	599
PC 32:3	728.52	3.82	0	0	0	0	0
PC 32:2	730.54	3.89	2	0	2	297	401
PC 32:1	732.56	3.85	1	1	2	421	537
PC 32:0	734.57	3.83	2	1347	1354	2131	2441
PC 34:3p/PC 34:4e	740.56	3.83	0	0	0	1	2
PC 33:3/34:2p/34:3e	742.58	3.90	0	1	0	879	1183
PC 33:2/34:1p/34:2e	744.59	3.83	3	8	10	1481	2019
PC 33:0/34:0e	748.59	3.83	4	925	916	902	977
PC 34:5	752.49	3.76	0	57	56	47	37
PC 34:4	754.55	3.93	1	2	4	168	221
PC 34:3	756.56	3.92	4	12	11	1280	1670
PC 34:2	758.58	3.89	12	14	10	70395	94527
PC 34:0/36:6p/36:7e	762.61	3.83	11	273781	263598	218540	230349
PC 35:5/36:4p/36:5e	766.58	4.13	0	1	2	4	6
PC 35:1/36:0p/36:1e	774.57	4.23	2	33	39	117	161
PC 35:0/36:0e	776.62	3.83	4	3476	3397	2896	2876
PC 36:6	778.55	3.98	1	117	113	260	297
PC 36:5	780.56	3.95	4	45	34	3552	4437
PC 36:4	782.58	3.92	1	8	7	25451	34306
PC 36:3	784.59	3.91	1	6859	6778	23985	29047
PC 36:2/38:8p/38:9e	786.61	3.88	10	902	774	39897	52463
PC 36:0/38:6p/38:7e	790.64	3.83	21	1011329	990992	792715	849723
PC 37:3/38:2p/38:3e	798.57	4.28	1	11	26	796	1152
PC 37:2/38:1p/38:2e	800.58	3.88	11	1038	1053	1278	1273
PC 37:1/38:0p/38:1e	802.60	4.23	2	210	180	245	148
PC 37:0/38:0e	804.57	3.93	6	2024	1903	3291	3310
PC 38:6	806.58	3.96	3	324	303	7779	11760
PC 38:5	808.59	3.95	2	395	369	8299	12033
PC 38:4	810.61	3.92	38	28438	27707	45181	50682
PC 38:0/40:6p/40:7e	818.66	3.83	11	4137	4031	4122	4515
PC 40:4p/40:6e	820.55	4.27	1	2	2	44	26
PC 40:4p/40:5e	822.62	3.93	9	276	264	1094	1243
PC 40:2p/40:3e	826.61	4.28	2	0	1	320	450
PC 40:6	834.61	3.96	5	112	101	5484	8033
PC 40:2/42:8p/42:9e	842.61	4.03	0	0	1	2	15
PC 40:1/42:7p/42:8e	844.55	3.96	1	4	4	132	163
PC 40:0/42:6p/42:7e	846.69	3.83	24	1236	1221	1183	1261
PC 42:5p/42:6e	848.65	3.94	3	91	81	480	551
PC 42:3p/43:4e	852.69	3.90	3	2	0	28	37
PC 42:2p/42:3e	854.58	4.00	3	2	4	48	117
PC 42:7/42:0e	860.72	3.83	25	209	191	161	169
PC 42:5	864.48	3.89	0	0	0	7	10
PC 42:4/42:10p	866.48	3.88	2	35	38	53	71
PC 42:2/44:8p/44:9e	870.51	3.82	0	55	51	49	56
PC 42:1/44:7p/44:8e	872.64	4.00	1	2	5	36	48
PC 44:5p/44:6e	876.70	3.93	3	68	70	401	550
PC 44:7/44:0e	888.75	3.84	22	2	2	4	2
PC 44:6	890.48	3.92	0	0	0	8	12
PC 44:5	892.51	3.90	0	0	0	6	9
PC 44:4	894.51	3.89	0	1	1	5	4
PC 44:3/46:9p/46:10e	896.54	3.83	7	386	385	340	346
PC 44:2/46:8p/46:9e	898.54	3.83	6	413	437	361	393
PC 44:1/46:7p/46:8e	900.69	3.98	1	1	1	17	35
PC 44:0/46:6p/46:7e	902.71	3.95	0	0	0	16	25
PC 46:5p/46:6e	904.72	3.94	1	2	2	20	35
PC 46:7/46:0e	916.58	3.76	0	90	92	208	133
PC std	790.78	3.85	146331	19045	56398	13140	44410
PE 30:0	664.43	4.75	0	3	0	5	2
PE 30:1	662.41	4.88	0	23	21	3	5
PE 34:0e	706.77	4.95	1	24	24	3	4
PE 36:2p/36:3e	728.46	4.86	0	5	3	7	6
PE 36:4p/36:5e	724.42	4.94	0	26	21	2	4
PE 38:0/40:6p/40:7e	776.56	4.70	5	4	6	98	273
PE 38:1/40:7p/40:8e	774.55	4.74	1	4	1	29	95
PE 38:2/40:8p/40:9e	772.53	4.69	1	0	0	9	46
PE 38:4	768.45	4.99	0	14	11	1	3
PE 38:5	766.55	4.69	2	6	4	35	72
PE 38:6	764.54	4.71	0	9	48	25	87
PE 38:6p/38:7e	750.55	4.68	8	1	8	183	389
PE 40:1/42:7p/42:8e	802.51	4.99	0	6	1	5	4
PE 40:2p/40:3e	784.59	5.23	0	2	64	5	74
PE 40:4/42:10p	796.54	4.73	0	3	0	2	10
PE 40:4p/40:5e	780.56	5.24	2	0	1	2	11
PE 40:5	794.57	4.66	0	0	0	2	6
PE 40:6	792.57	4.70	0	1	3	3	9
PE 42:2/44:8p/44:9e	828.59	4.78	0	8	42	4	44
PE 42:2p/42:3e	812.48	5.07	0	12	8	2	5
PE 42:3p/42:4e	810.60	4.89	3	1	2	4	5
PE 42:4p/42:5e	808.59	4.68	1	7	7	8	78
PE 42:5p/42:6e	806.58	4.79	0	0	1	0	1
PE 42:8/42:0p/42:1e	816.52	5.03	1	6	1	8	8
PE 42:9/42:1p/42:2e	814.69	4.77	2	0	1	0	4
PE 44:0/46:6p/46:7e	860.54	5.15	0	0	0	3	2
PE 44:3p/44:4e	838.56	4.79	0	11	9	1	0
PE 44:8/44:0/44:1e	844.57	4.79	0	23	21	2	5
PE 46:0/48:6p/48:7e	888.60	4.86	0	81	88	12	23
PE 46:1/48:7p/48:8e	886.62	4.72	30	0	15	1	14
PE 46:3/48:9p/48:10e	882.58	4.86	0	12	19	1	4
PE 46:6	876.85	4.74	54	0	46	0	44
PE 46:9/46:1p/46:2e	870.79	4.71	99	0	15	1	11
PE 48:2	912.61	4.90	0	20	14	2	2
PE 48:6	904.58	5.14	0	5	0	1	0
PE 48:7/48:0e	902.94	4.89	0	75	67	6	9
PE std	748.53	4.70	23363	7	17432	6	13859
SM 32:1	675.55	4.31	2	0	5	1221	1803
SM 32:2	673.53	4.35	1	1	0	64	97
SM 33:2	689.56	4.31	1	1	0	861	1238
SM 34:1	703.58	4.30	5	1	2	29191	44752
SM 34:2	701.56	4.33	8	3	5	2265	3772
SM 35:0	719.57	4.68	1	1	1	32	134
SM 35:1	717.59	4.30	3	1	1	531	797
SM 35:2	715.58	4.33	1	0	1	49	78
SM 36:1	731.46	4.36	1	77	59	105	64
SM 36:2	729.59	4.33	3	1	0	1632	2684
SM 38:3	755.58	4.54	2	0	2	1	28
SM 38:4	753.59	4.30	10	5	11	1223	1311
SM 38:5	751.58	4.34	0	1	1	412	503
SM 39:0	775.49	4.43	1	104	75	181	108
SM 39:4	767.59	4.29	1	1	0	109	118
SM 39:5	765.59	4.33	2	6	5	32	46
SM 40:0	789.50	4.47	0	1	1	4	2
SM 41:0	803.61	4.38	1	40	26	101	104
SM 41:1	801.69	4.28	9	294	257	3744	5798
SM 41:2	799.67	4.31	3	2	6	1845	2784
SM 41:3	797.65	4.35	0	0	0	208	298
SM 41:4	795.64	4.28	3	3	2	376	419
SM 41:6	791.95	4.61	0	13	10	1	1
SM 42:2	813.69	4.32	39	302	654	17966	29873
SM 42:3	811.67	4.35	9	201	318	5109	8498
SM 43:0	831.64	4.37	3	1	1	138	198
SM 43:1	829.69	4.53	13	0	12	6	101
SM 43:2	827.70	4.31	8	42	126	606	947
SM 43:4	823.67	4.28	7	6	5	1185	1341
SM 43:5	821.66	4.32	2	4	3	480	544
SM 43:6	819.52	4.49	1	94	69	191	117
SM 44:1	843.73	4.28	14	1	13	13	54
SM 44:2	841.53	4.53	0	99	56	191	87
SM 44:5	835.67	4.32	82	11	99	4237	5488
SM 44:6	833.66	4.35	7	3	15	1297	1941
SM 46:5	863.55	4.57	1	93	58	189	101
SM 46:7	859.67	4.28	2	0	1	13	14
SM std	734.77	4.29	46209	6	40032	4	36207
TG 39:1	679.43	1.10	0	22	27	30	38
TG 40:2	708.52	1.13	0	71	35	46	32
TG 42:0	740.68	1.10	0	0	5	65	125
TG 42:1	738.67	1.12	0	0	0	94	164
TG 42:2	736.65	1.14	0	2	1	84	139
TG 42:4	732.62	1.31	0	56	114	43	51
TG 44:1	766.70	1.14	3	2	13	889	1340
TG 44:2	764.68	1.15	1	0	1	428	518
TG 44:3	762.67	1.16	0	0	0	108	117
TG 45:1	780.72	1.15	2	1	10	141	202
TG 45:2	778.56	1.13	0	214	113	130	107
TG 45:3	776.69	1.16	0	0	0	17	18
TG 46:1	794.73	1.16	15	12	63	3547	4096
TG 46:2	792.71	1.17	1	1	10	1607	1700
TG 46:3	790.70	1.18	0	0	1	445	476
TG 46:4	788.68	1.19	0	0	2	116	123
TG 46:5	786.67	1.19	0	0	1	13	12
TG 47:0	810.58	1.13	0	29	10	18	13
TG 47:1	808.74	1.17	11	6	25	545	588
TG 47:2	806.73	1.17	0	5	10	217	215
TG 47:5	800.69	1.20	0	0	0	19	16
TG 48:1	822.76	1.17	12	24	80	10060	10820
TG 48:2	820.74	1.18	3	4	12	5917	6593
TG 48:3	818.73	1.19	0	1	0	2462	2840
TG 48:4	816.71	1.20	0	4	1	931	967
TG 48:5	814.70	1.20	1	1	16	194	207
TG 49:1	836.78	1.18	4	12	20	1649	1815
TG 50:2	848.73	1.38	1	9	9	13	1
TG 50:3	846.76	1.20	5	13	14	13970	14530
TG 50:4	844.75	1.21	9	12	8	5298	5610
TG 50:5	842.73	1.22	19	9	45	1126	1286
TG 52:2	876.98	1.20	1	0	0	152	110
TG 52:3	874.79	1.48	13	0	7	3	79
TG 52:4	872.95	1.23	7	0	7	84	219
TG 53:0	894.76	1.27	22	11	19	4292	5626
TG 53:1	892.75	1.45	0	11	5	11	6
TG 53:4	886.79	1.23	3	370	49	1253	1567
TG 54:0	908.86	1.29	0	158	386	134	338
TG 54:1	906.80	1.24	6	360	529	3546	3999
TG 54:4	900.77	1.20	1	1	0	31	10
TG 54:5	898.79	1.24	43	11	66	27457	38015
TG 54:6	896.78	1.26	105	6	81	14946	20253
TG 55:2	918.75	1.29	7	2	2	952	1243
TG 56:1	934.80	1.29	1	18	23	464	605
TG 56:4	928.77	1.40	0	8	2	15	33
TG 56:6	924.81	1.26	8	514	87	15906	21743
TG 56:7	922.79	1.28	0	15	25	5807	8505
TG 56:8	920.77	1.28	1	2	0	2533	3761
TG 57:2	946.79	1.31	1	0	3	2350	3770
TG 57:3	944.77	1.31	0	3	7	682	977
TG std	869.84	1.19	272218	64	137321	25988	165121
FFA 16:0	257.24	1.66	0	0	0	1	0
FFA 16:1	255.31	1.52	1	2	1	2	0
FFA 18:1	283.35	1.54	2	31	33	19	3
FFA 18:2	281.33	1.56	1	1	0	0	1
FFA 18:3	279.23	1.60	0	92	111	468	532
FFA 20:1	311.22	1.85	2	10	15	11	8
FFA 20:3	307.26	1.61	0	9	11	36	53
FFA 20:5	303.23	1.68	0	0	3	29	58
FFA 22:0	341.26	1.78	0	4	4	2	3
FFA 22:1	339.32	1.57	19	259	327	227	252
FFA 22:2	337.31	1.61	0	6	11	14	8
FFA 22:4	333.27	1.71	0	0	0	0	0
FFA 22:5	331.26	1.67	0	1	1	2	6
FFA 22:6	329.24	1.71	0	0	0	1	0
FFA 24:0	369.30	1.80	0	11	22	9	9
FFA 24:1	367.35	1.57	29	332	396	336	364
FFA 24:2	365.34	1.62	0	2	2	13	27
FFA 24:3	363.32	1.65	0	0	0	0	7
FFA 24:4	361.23	1.60	0	0	0	0	1
FFA 24:5	359.29	1.69	0	1	0	0	0
FFA std	286.42	1.50	33886	86	42274	116	24636

TABLE 7
Mass Spectrometry-based lipidomic analysis.
List of all ceramides identified in healthy human plasma and onto
the surface of HSPC:CHOL liposomes, as these were found
by LC-MS/MS. All samples were run in two technical replicates.
Abundance values are shown below for all ceramides identified.
				Corona-	Corona-	Average
	Bare	Bare	Average	coated	coated	Corona-
Compound	NPs 1	NPs 2	Bare NPs	NPs 1	NPs 2	coated NPs
CER(N(14)S(18))	0.005	0.004	0.0045	0.086	0.104	0.095
CER(N(16)S(18))	0.047	0.043	0.045	1.207	1.274	1.2405
CER(N(18)S(18))	0.016	0.008	0.012	0.367	0.365	0.366
CER(N(20)S(18))	0	0	0	0.516	0.477	0.4965
CER(N(22)S(18))	0.022	0.026	0.024	5.044	5.014	5.029
CER(N(23)S(18))	0	0	0	4.92	4.726	4.823
CER(N(24)S(18))	0.09	0.095	0.0925	20.65	19.72	20.185
CER(N(26)S(18))	0.052	0.066	0.059	0.382	0.389	0.3855
CER(N(24)S(16))	0.016	0.019	0.0175	0.928	0.872	0.9
CER(N(24)S(17))	0.009	0.013	0.011	0.706	0.678	0.692
CER(N(22)S(19))	0	0	0	0.228	0.249	0.2385
CER(N(24)S(19))	0	0	0	1.211	1.252	1.2315
CER(N(26)S(19))	0	0	0	0.032	0.024	0.028
CER(N(23)S(20))	0	0	0	0.04	0.05	0.045
CER(N(24)S(20))	0.018	0.02	0.019	0.233	0.208	0.2205
CER(N(25)S(20))	0	0	0	0.021	0.022	0.0215
CER(N(24)S(22))	0	0	0	0.019	0.022	0.0205
CER(N(16)DS(18))	0	0	0	0.546	0.571	0.5585
CER(N(18)DS(18))	0	0	0	0.509	0.529	0.519
CER(N(22)DS(18))	0	0	0	1.422	1.843	1.6325
CER(N(25)DS(18))	0	0	0	0.108	0.152	0.13
CER(N(24)DS(19))	0	0	0	0.202	0.202	0.202
CER(N(24)DS(20))	0.14	0.168	0.154	0.238	0.226	0.232
CER(N(18)DS(24))	0	0	0	1.656	1.572	1.614
CER(N(20)DS(24))	0.074	0.084	0.079	0.121	0.135	0.128
CER(A(18)S(18))	0.738	0.766	0.752	0.892	0.986	0.939
CER(A(20)S(18))	0	0	0	0.137	0.136	0.1365
CER(A(22)S(18))	0	0	0	0.319	0.326	0.3225
CER(A(18)DS(18))	0	0	0	0.221	0.221	0.221
CER(A(20)DS(18))	1.001	1.001	1.001	1.062	1.017	1.0395
CER(A(22)DS(18))	1.262	1.445	1.3535	1.515	1.503	1.509
CER(A(24)DS(18))	0.602	0.808	0.705	0.821	0.827	0.824
CER(A(24)H(16))	0	0	0	3.249	3.364	3.3065
CER(A(25)H(16))	0	0	0	13.355	14.433	13.894
CER(A(26)H(26))	0	0	0	0.983	1.028	1.0055
CER(A(27)H(16))	0	0	0	0.25	0.224	0.237
CER(A(25)H(18))	0	0	0	0	0	0

TABLE 8
Mass Spectrometry-based lipidomic analysis.
List of all oxylipins identified in healthy human plasma and onto the
surface of HSPC:CHOL liposomes, as these were found
by LC-MS/MS. All samples were run in two technical replicates.
Abundance values in pg/uL are shown below for all oxylipins identified.
		Bare	Bare	Average	Corona-	Corona-	Average
	Lipid	NPs	NPs	Bare	coated	coated	Corona-
Compound	Cocktail	1	2	NPs	NPs 1	NPs 2	coated NPs
9(10) EpOME	18	0	0	0	0	0	0
12(13) EpOME	19.2	0	0	0	0	0	0
9,10 DiHOME	18.1	0	0	0	0	0	0
12,13 DiHOME	22	0.6	0.7	0.65	0.5	0.8	0.65
17,18-DiHETE	21.7	0	0	0	0	0	0
5,15 DiHETE	20.6	0	0	0	2	1.6	1.8
8,15 DiHETE	20.7	0	0	0	2.5	2.4	2.45
11,12 DHET	19.3	0	0	0	0	0	0
14,15 DHET	17.8	0	0	0	0	0	0
9 HOTrE	18.4	0	0	0	0.6	0.8	0.7
13 HOTrE	22	0	0	0	1.8	1.6	1.7
9 HODE	21.2	0	0	0	64.5	75.8	70.15
13 HODE	20.7	2.9	3.3	3.1	53.5	61.3	57.4
5 HEPE	22	0	0	0	2.2	1.6	1.9
8 HEPE	21.3	0	0	0	0.7	1	0.85
11 HEPE	22.4	0	0	0	1.2	1.4	1.3
12 HEPE	22.5	0	0	0	0.6	0.8	0.7
18 HEPE	21.8	0	0	0	3	3	3
5-oxo-ETE	15	0	0	0	16.9	14.8	15.85
15-oxo-ETE	17.4	0	0	0	25.2	21.4	23.3
5 HETE	17	0	0	0	34	41.1	37.55
8 HETE	18.1	0	0	0	8.2	8.3	8.25
9 HETE	17.8	0	0	0	10.9	12.5	11.7
11 HETE	21.8	0	0	0	20.1	20.6	20.35
12 HETE	15.8	0	0	0	10.9	10.7	10.8
15 HETE	24.1	0	0	0	18.2	21.1	19.65
20 HETE	24	0	0	0	0	0	0
15 HETrE	19.5	0	0	0	3.7	4.1	3.9
LTB4	25.8	0	0	0	4.2	5	4.6
4 HDHA	19.7	0	0	0	2.1	2.2	2.15
8-HDHA	17.3	0	0	0	2.4	2.8	2.6
10 HDHA	20.9	0	0	0	2.1	2	2.05
13 HDHA	22.5	0	0	0	3.1	4	3.55
14 HDHA	21.5	0	0	0	3.1	2.9	3
17 HDHA	23.6	0	0	0	6.8	7.8	7.3
20 HDHA	26	0	0	0	5.3	5.3	5.3
LXA4	21.7	0	0	0	2.8	3.1	2.95
13,14 DiHDPA	23	0	0	0	0	0	0
16,17 DIHDPA	18.9	0	0	0	0	0	0
19,20 DiHDPA	16.6	0	0	0	0	0	0
9 OxoODE	16	1.5	1.2	1.35	10.8	8.9	9.85
13 OxoODE	19.9	0	0	0	333.9	333.5	333.7
Trans EKODE	28.3	0.9	0.6	0.75	6	4.6	5.3
PDX (10(S) 17(S	23.3	0.4	0.7	0.55	1.3	1.7	1.5
DIHDPA)		23.3

REFERENCES

• 1 Hadjidemetriou and Kostarelos, Nat. Nanotechnol., 2017, 12, 288-290
• 2 Dai et al. Adv. Healthc. Mater., 2018, 7, 1700575
• 3 Chen et al. Nanoscale, 2019, 11, 8760-8775
• 4 Debayle et al. Biomaterials, 2019, 219, 119357
• 5 Müller et al. Biomaterials, 2017, 115, 1-8
• 6 Docter et al. Nanomedicine, 2015, 10, 503-519
• 8 Hadjidemetriou et al. Biomaterials, 2019, 188, 118-129
• 9 Hadjidemetriou et al. Adv. Mater., 2019, 31, 1-9
• 10 Papafilippou et al., Nanoscale, 2020, 12, 10240-10253
• 11 Al-Ahmady et al. J. Control. Release, 2018, 276, 157-167
• 13 Hadjidemetriou et al. Nano Today, 2020, 34, 100901
• 14 Hadjidemetriou et al. ACS Nano, 2015, 9:8142-8156
• 15 Rasoulianboroujeni et al. Mater. Sci. Eng. C, 2017, 75, 191-197
• 36 Sioud and Sorensen, Biochem. Biophys. Res. Commun., 2003, 312, 1220-1225
• 42 K. Hamad-Schifferli, Nanomedicine, 2015, 10, 1663-1674
• 43 No et al., Anticancer Res., 2012, 32, 3467-71
• 44 Kamat et al., Cancer, 2010, 116, 1918-1925
• 45 Kowal et al., Proc. Natl. Acad. Sci. U.S.A, 2016, 113, E968-E977
• 47 Schwarzenbach et al. Nat. Rev. Cancer, 2011, 11, 426-437
• 48 Snyder et al., Cell, 2016, 164, 57-68
• 52 Dobrovolskaia et al., Nanomedicine Nanotechnology, Biol. Med., 2014, 10, 1453-1463
• 53 De Paoli et al., Biomaterials, 2014, 35, 6182-6194
• 54 Valpione et al., Eur. J. Cancer, 2018, 88, 1-9
• 55 Bagley et al., Clin. Cancer Res., 2020, 26, 397-407.
• 56 Hao et al., Br. J. Cancer, 2014, 111, 1482-1489
• 57 Fernandez-Garcia et al., Breast Cancer Res., 2019, 21, 149
• 58 Mizuno et al., Sci. Rep., 2019, 9, 1-11
• 59 Kuroi et al., Int. J. Oncol., 2001, 19, 143-148
• 60 Holdenrieder et al., in Annals of the New York Academy of Sciences, New York Academy of Sciences, 2008, vol. 1137, pp. 180-189
• 61 Kumar et al., Clin. Lung Cancer, 2010, 11, 36-44
• 62 de Miguel Perez et al. Sci. Rep., 2020, 10, 1-13
• 63 Liu et al., Ann. Oncol., 2020, 31, 745-759
• 64 Sina et al., Nat. Commun., 2018, 9, 1-13
• 65 Nguyen and Sim, Biosens. Bioelectron., 2015, 67, 443-449
• 66 Esteller, Nat. Rev. Genet., 2007, 8, 286-298
• 67 Kurdistani, Br. J. Cancer, 2007, 97, 1-5
• 68 Fraga and Esteller, Cell Cycle, 2005, 4, 1377-1381
• 69 Deligezer et al., Clin. Chem., 2008, 54, 1125-1131
• 70 Gezer et al., Oncol. Lett., 2012, 3, 1095-1098
• 71 Gezer et al., Int. J. Mol. Sci., 2015, 16, 29654-29662
• 73 Rago et al. Cancer Res., 2007, 67, 9364-9370

Claims

1. A method of identifying biomarkers from two or more distinct biomolecule classes in a biofluid, wherein the method comprises: (a) contacting a plurality of nanoparticles with a biofluid to allow a biomolecule corona to form on the surface of said nanoparticles;(b) isolating the nanoparticles and surface-bound biomolecule corona; and(c) analyzing the biomolecule corona to identify biomarkers from two or more distinct biomarker classes.

2. The method according to claim 1, wherein step (a) is performed in vivo by administering a plurality of nanoparticles to a subject or in vitro using a biofluid

3. The method according to claim 2, wherein the nanoparticles are administered to a subject by intravenous injection.

4. The method according to claim 1, wherein the plurality of nanoparticles are incubated in the test biofluid sample in vitro under conditions to allow a biomolecule corona to form on the surface of said nanoparticles.

5. The method according to claim 1, wherein the analysis is conducted on a single biofluid sample.

6. The method according to claim 1, wherein the biofluid is a blood or blood fraction sample, optionally selected from serum or plasma.

7. The method according to claim 1, wherein at least one of the biomarker classes is selected from the group consisting of: protein, nucleic acid and lipid (or complexes of these).

8. The method according to claim 1, wherein the biomolecule corona is analyzed by two or more of proteomic, genomic and lipidomic analysis.

9. The method according to claim 1, wherein the biomolecule corona is analyzed by genomic analysis and at least one other biomarker class of analysis.

10. The method according to claim 9, wherein the biomolecule corona is analyzed by genomic analysis and proteomic and/or lipidomic and/or metabolomic analysis.

11. The method according to claim 1, wherein the nanoparticles are selected from liposomes, metallic nanoparticles (such as gold or silver), polymeric nanoparticles, fibre-shaped nanoparticles (such as carbon nanotubes and two dimensional nanoparticles such as graphene oxide nanoparticles; optionally wherein the nanoparticles are liposomes.

12. (canceled)

13. The method according to claim 11, wherein the nanoparticles are negatively charged.

14. The method according to claim 1, wherein the nanoparticles with surface-bound biomolecule corona are isolated from the biofluid and purified to remove unbound and highly abundant biomolecules to allow identification of low abundant biomarkers; optionally wherein the nanoparticles with surface-bound biomolecule corona are isolated from the biofluid and purified to remove unbound and highly abundant biomolecules by a method comprising size exclusion chromatography followed by ultrafiltration.

15. (canceled)

16. The method according to claim 1, wherein the biofluid sample analyzed is from a subject in a diseased state, such as cancer, optionally wherein the cancer is selected from the group consisting of: lung, melanoma or ovarian cancer.

17. The method according to claim 1, wherein one of the biomarker classes being analyzed is nucleic acid, such as DNA or RNA; optionally wherein the nucleic acid is cell-free DNA (cfDNA), optionally wherein the cfDNA is genomic DNA.

18. (canceled)

19. The method according to claim 17, wherein the amount or relative amount of total cell-free DNA (cfDNA) is determined.

20. The method according to claim 17, wherein a specific nucleic acid sequence within the cell-free nucleic acid is determined, optionally wherein the specific nucleic acid is indicative of a disease, such as being or comprising a disease-associated mutation.

21. The method according to claim 1, wherein a change in a biomarker in a biofluid from a subject in response to therapy is monitored; optionally wherein the therapy comprises administration of a drug molecule to the subject, optionally wherein the drug molecule is an anti-cancer compound.

22. (canceled)

23. A method for detecting a disease state in a subject, comprising: (a) contacting a biofluid sample from the subject with a plurality of nanoparticles under conditions to allow a biomolecule corona to form on the surface of said nanoparticles; and(b) analyzing the biomolecule corona for one or more disease-specific biomarkers from two or more biomolecule classes, which is determinative of the presence of a disease in said subject.

24. A method for monitoring cancer progression in a subject, comprising: (a) contacting a biofluid sample from the subject with a plurality of nanoparticles under conditions to allow a biomolecule corona to form on the surface of said nanoparticles; and(b) analyzing the biomolecule corona for one or more cancer-specific biomarkers from two or more biomolecule classes; wherein the degree of cancer progression is determined based on the level of the cancer-specific biomarker(s) relative to a reference amount;optionally wherein the cancer is selected from the group consisting of: ovarian, lung, prostate, melanoma and blood cancer, including leukemia, lymphoma and myeloma.

25. (canceled)