The present invention relates to compositions and methods for the prevention and treatment of non-melanoma skin cancer (NMSC).
Non-melanoma skin cancer (NMSC) is the most common form of cancer worldwide. NMSC includes all forms of skin cancer that do not start in melanocytes, most notably basal cell carcinoma (BCC) (around 75-80% of all NMSCs) and squamous cell carcinoma (SCC) (around 20-25% of all NMSCs).
Actinic Keratosis (AK) is an important NMSC entity. Historically, it was considered to be a precursor lesion of SCC. Nowadays, the scientific community understands it to be a carcinoma in situ that may progress to an invasive stage. In contrast to the other NMSCs, AK is highly abundant.
AK is a skin disease that typically develops on areas of chronic sun exposed skin. The change in the pathophysiological concept of AK, which is now considered a carcinoma in situ, is driven by the facts that at the level of cytology AK is indistinguishable from SCC, and at the level of molecular biology, it shares multiple similarities with SCC.
AK is classified histopathologically in 3 grades (AK I-III) based on the extent of atypical keratinocytes in the epidermis. Clinically, AKs typically presents as scaly patches on an erythematous base. Palpation reveals a sand paper-like texture. The surrounding skin may show signs of chronic sun damage including telangiectasias, dyschromia and elastosis. Dermoscopy supports both differential diagnosis (e.g., of pigmented lesions on the face) and clinical grading. The anatomical distribution (face, bald head, neck, back of the hand) further highlights the importance of chronic sun exposure as major risk factor for the development of AKs. Other risk factors include advanced age, male gender and fair skin type. Immunosuppression (e.g. transplant recipients) also confers a higher risk for AKs. UVB radiation can lead to direct DNA damage. As a result, the function of tumour suppressor proteins such as p53 is suppressed. In fact, dysregulation of the p53 pathway seems to play the most important role in the development of AK lesions and their further progression to SCC. Some evidence suggests infections with human papilloma viruses act as cofactors.
AKs may occur as single lesions (≤5) as multiple lesions (≥6) or multiple lesions (≥6) in the context of field cancerization (i.e. at least 6 AK lesions in one body region or field, and contiguous areas of chronic sun damage). The common classification recommends a fourth subgroup, immunosuppressed patients with AKs.
Data available on the natural history of AK indicate that the presence of AK without adequate treatment is a dynamic but chronic condition. The risk of progression from AK to invasive SCC is estimated at 10% for individual lesions. As it is currently impossible to predict which AK lesions will progress to SCC, it is important to intervene as soon as possible in all cases.
Current AK therapies can be divided into two main classes: lesion directed and field directed. The most common lesion directed therapy is cryosurgery followed by surgical removal. The major drawback of both lesion-directed methods is that they are only able to address visible lesions but not the damaged field. Moreover, their cosmetic results are judged to be inferior to those of field-directed treatments. For these reasons, field-directed therapies are increasingly being used to eliminate not only clinically visible lesions, but also subclinical lesions to prevent their transition to SCC.
Current field directed therapies include topical agents such as Imiquimod (sold as Aldara®, Zyclara®), Diclofenac (sold as Solaraze®), 5-fluorouracil (sold as Efudix® or Actikerall®), ingenol mebutate (sold as Picato®) and photodynamic therapy (Ameluz®, Metvix®). Field therapies have the potential to affect subclinical lesions.
These current state of the art treatments often require an extensive treatment period with frequent home applications and a substantial down time. This is decreasing patient compliance severely and limiting efficacy of NMSC treatments in clinical practice. Additionally, responder rates to existing treatments vary, with histological clearance rates of AK following standard treatment reported as low as 67% following fluorouracil and 73% following Imiquimod. Information on the long-term effectiveness and recurrence rates of field-directed therapies is scarce and unimpressive. Recurrence rates at the 1-year time point range from 10 to 56%.
These unimpressively low success rates warrant the development of novel treatment paradigms to meet the medical need in the treatment of NMSCs.
Interferon alpha (Interferon α, IFN-α, IFNa), a type I interferon, exhibits antiviral, antiangiogenic as well as proapoptotic properties and is a key immunostimulatory molecule with proven therapeutic anti-tumoural efficacy. Interferons were first described in 1957. Cloning of genes for IFNa, and later, Interferon beta (IFN-β; IFNb) and Interferon gamma (IFN-γ; IFNg) was only reported in the early 1980s.
In the 1980s, recombinant IFNa protein has been suggested for the treatment of AKs and other forms of NMSC. At that time, multiple reports claimed the safety and efficacy of recombinant IFNa protein for the treatment of BCC and SCC. Repeated perilesional administration at a dose of 1.5×106 IU IFNa 3× a week for 3 weeks was found adequate for most BCCs and SCCs (large tumours required higher total doses).
U.S. Pat. Nos. 5,002,764 A and 5,028,422 A disclose an intralesional administration treatment of AKs, with recombinant human IFNa-2 protein.
Various BCC subtypes appear to respond differently with superficial and ulcerative types being more amenable to IFNa therapy than nodular types. Intralesional administration of recombinant human IFNa-2b three times over a period of three weeks for the treatment of human BCC is also discussed in EP 0 248 583 B1.
SCC is generally more aggressive than BCC and potentially life-threatening. The overall 5-year recurrence rate of primary skin SCC is 8% (compared to BCC<0.1%).
There are a few reports on studies assessing intralesional IFNa in squamous cell carcinomas.
Frequent and long lasting application of high dose intralesional IFNa is effective in the treatment of small squamous cell carcinomas. For AK, Edwards and colleagues reported 6 perilesional injections of high dose, 5×105 IU per dose to clear AKs (Arch. Dermatol., 1986. 122(7): p. 779-82). Lower doses of IFNa protein (1×105, 1×104 IU per injection) proved less effective in AK clearance in situ, respectively.
The mechanism of action of IFNa in the treatment of the various types of NMSC is partially known. The antitumor effect appears to be due to a combination of direct antiproliferative, as well as indirect effects, relying on the tumour stroma and microenvironment. The latter includes effects on both the innate and adaptive immune system as well as on the tumour vessels. Effectiveness of IFNa in Kaposi's sarcoma and hemangiomas demonstrates the clinical relevance of its antiangiogenic activity.
While IFNa has been shown to be effective in NMSC, in particular in AK, BCC and SCC, it never became a therapeutic option for clinical routine. The reasons are obvious. Treatment requires frequent (daily or three times weekly) perilesional injections over several weeks. Also, recombinant IFNa protein was expensive and the quality and importantly bioactivity of the preparations differed. IFNa was produced by recombinant DNA technology using a genetically engineered E. coli strain. Although expression by E. coli lead to high protein yield, the product had to be extensively purified and tested for potency and bioactivity in order to provide a comparable level of bioactivity for treatment with varying degree of non-active and active protein in the product.
The reason why there is a desire in modern medicine to avoid Interferons, especially IFNa, is that these proteins have a number of characteristic toxic effects. Four major groups of side-effects occur: constitutional, neuropsychiatric, hematological/immunological and hepatic. The severity of many of these side-effects appears to be directly related to the dose and duration of IFN protein therapy (Borden et al., Semin Oncol, 1998. 25(1 Suppl 1): p. 3-8).
Constitutional symptoms include influenza-like symptoms such as fatigue, fever, chills and rigor. Constitutional symptoms occur early, often within 3-6 hours after dosing. Patients may also experience headaches, myalgias, and malaise. Transaminitis and neutropenia may occur within the first few days of treatment and can be controlled by reducing the dose. Transaminitis, if not handled appropriately, can result in fatal hepatotoxicity. The most frequent chronic symptoms experienced by patients on IFN include fatigue (70-100%), anorexia (40-70%) and neuropsychiatric disorders (up to 30%). These symptoms are dose related and cumulative, worsening over time. Auto-immune toxicities include triggering of lupus erythematosus, psoriasis and thyroid dysfunction. Thyroid dysfunction, ranging from overt to subclinical hyper- or hypothyroidism, occurs in 8-20% of patients receiving IFNa therapy. The pattern followed by most patients is one of an autoimmune thyroiditis, with a period of hyper-followed by hypothyroidism.
The need to replace protein Interferons, especially IFNa protein has i.a. led to the enormous market success of the combination of ledipasvir/sofosbuvir (sold under the trade name Harvoni) in the treatment of hepatitis C (replacing IFNa (in combination with ribavirin)).
However, also these commercially successful treatment options for NMSCs, especially AKs show significant adverse effects and limited efficacy in the course of treatment: Of note, in special individuals, local IFN inducers like the TLR7 agonist Imiquimod may lead to more concerning types of autoimmune toxicity such as the development of subacute cutaneous lupus erythematosus. Furthermore, certain individuals also carry single nucleotide polymorphisms in TLR7 which makes them non-responders to TLR7 agonists like Imiquimod (Pharmacogenomics. 2015. November; 16 (17): p. 1913-17).
Accordingly, there is still a significant medical need for improved prevention and treatment schemes for NMSC providing improved patient's compliance and improved adverse reaction events.
Current field directed therapies represent a heterogenic class of topical agents including Imiquimod, Ingenol mebutate, Diclofenac and photosensitizers for photodynamic therapy (PDT) and fluorouracil. These current state-of-the-art treatments show histological clearance rates of AK following standard treatment reported as low as 67% following fluorouracil and 73% following Imiquimod. All of these current state of the art agents rely on an either immediately direct (e.g.: fluorouracil, ingenol mebutate, PDT) or indirect mechanism (imiquimod) for NMSC/AK therapy.
Imiquimod, one of the most widely used therapeutic agents, acts through activation of the innate immune system which in turn exerts anti-tumor activity.
Imiquimod application activates Toll-like receptor 7 (TLR7) signalling, which is commonly involved in pathogen recognition. Importantly, epidermal keratinocytes, as target cells for Imiquimod activity in NMSC, constitutively express several members of the TLR family. However, TLR7 expression is either absent or only very scarcely detectable. Thus, a direct effect of Imiquimod on keratinocytes is rather unlikely.
In contrast, there is compelling evidence for an indirect anti-tumor-function of Imiquimod: Imiquimod activates innate immune cells via TLR-7 which leads to extensive secretion of cytokines, primarily interferon-α (IFNa), interleukin-6 (IL-6), and tumour necrosis factor-α (TNF-α), among others, and to the rapid recruitment of plasmacytoid dendritic cells (pDCs) to the skin application side. Imiquimod induces pDC maturation and their conversion into cytolytic killer cells, which are capable of eliminating tumours independently of the adaptive immune system. Other cell types activated by Imiquimod include natural killer cells, and macrophages. In addition, there is also compelling evidence that Imiquimod, when applied to skin topically, leads to the activation of Langerhans cells, which subsequently migrate to local lymph nodes to activate the adaptive immune system including B-lymphocytes.
In contrast to the mere indirect effects of Imiquimod or the mere direct effects of fluorouracil, ingenol mebutate and PDT on aberrant cells in NMSC, BCC, SCC and especially AK, IVT mRNA mediated IFNa protein expression is exerting specific direct and indirect effects on affected cells (e.g.: keratinocytes which have been successfully transfected and are expressing IFNa). IFNa is known to directly affect apoptosis, proliferation or cellular differentiation of tumour cells resulting from induction of a subset of genes, called IFN stimulated genes (ISGs). In addition to the ISGs implicated in anti-angiogenic, immunomodulatory and cell cycle inhibitory effects, oligonucleotide microarray studies have identified ISGs with apoptotic functions. These include TNF-α related apoptosis inducing ligand (TRAIL/Apo2L), Fas/FasL, XIAP associated factor-1 (XAF-1), caspase-4, caspase-8, dsRNA activated protein kinase (PKR), 2′5′A oligoadenylate synthetase (OAS), death activating protein kinases (DAP kinase), phospholipid scramblase, galectin 9, IFN regulatory factors (IRFs), promyelocytic leukaemia gene (PML) and regulators of IFN induced death (RIDs). Of note, IFNa will also exploit indirect anti tumor activity as excerted by immune modulators as it is currently expected to constitute one of the major factors involved in excerting anti tumor activity of Imiquimod.
IVT mRNA based IFNa expression is thus showing the potential to change the current state-of-the-art in treating NMSC, BCC, SCC and especially AK by exploiting several anti-tumour strategies (direct and indirect) simultaneously. Specifically, the direct IFNa activity in target cells, and, as the current state-of-the-art approach using immune modulators, activation of cells of the innate immune system and subsequent anti-tumour activity. By doing so one can readily imagine that such a dual strategy enhances overall activity of the treatment as it may enhance efficacy and/or enlarge the subset of patients responding to therapy.
A further object of the present invention is to provide methods which are easily reversible and do not have severe impact on the patient's body as a whole (i.e. (adverse) systemic consequences due to the treatment). Moreover, it is a desire to provide cytokine treatment without the normally accompanied burden for the patients and to increase treatment efficiency, responder rates and patient compliance.
Therefore, to overcome the limitations of current treatement options summarized above, the present invention provides Interferon alpha (IFN-α) messenger-RNA (mRNA), wherein the mRNA has a 5′ CAP region, a 5′ untranslated region (5′-UTR), a coding region, a 3′ untranslated region (3′-UTR) and a poly-adenosine Tail (poly-A Tail), for use in the prevention and treatment of non-melanoma skin cancer (NMSC).
Surprisingly, it was possible to apply IFN-α mRNA to patients suffering from NMSC, without the undue consequences known to be associated with administration of (recombinant) IFN-α protein. The present invention allows e.g. local administration on or into the skin of NMSC patients, especially patients suffering from actinic keratosis (AK), without the systemic adverse effects normally connected with IFN-α treatment.
Importantly, the present invention uses the full length IFNa precursor molecules instead of the recombinant molecule: e.g.: recombinant human IFNa2a used for clinical applications so far, is a 165aa long protein of bacterially manufactured origin, whereas the construct used in this invention is producing a fully human 188aa precursor protein in the transfected cells. This full-length precursor is intracellularly processed to allow for formation of the secreted bioactive protein of 165aas. Importantly, and in contrast to recombinant proteins like the bacterially produced Roferon A, this naturally processed protein is also including naturally occurring posttranslational modifications required for full bioactivity in mammals, especially humans. Thus, in contrast to recombinant, purified IFNas, all protein produced from IVT mRNA as presented in this invention is expected to have 100% bioactivity locally, in the intended target organ without major systemic exposure.
This is in contrast to recombinant IFNa, where only a portion of the recombinant material is bioactive and due to the high protein doses and injection volumes as well as mode of application, is also systemically active. E.g. after intramuscular injection of Roferon A, the bioavailability was greater than 80%. After intramuscular and subcutaneous administration of 36 million IU, peak serum concentrations ranged from 1,500 to 2,580 pg/ml (mean: 2,020 pg/ml) at a mean time to peak of 3.8 hours, and from 1,250 to 2,320 pg/ml (mean: 1,730 pg/ml) at a mean time to peak of 7.3 hours, respectively (Israeli ministry of health (MOH) approved prescribing information December 2001). Interestingly, recombinant IFNa is eliminated quickly following bolus applications with an average elimination half-life of 5.1 h, explaining the need for the frequent and high dose application required for NMSC treatment in patients.
With the present invention, the drawbacks of the IFNa protein therapies known in the art were surprisingly overcome. On the other hand, instead of further developing the protein administration further (by providing better IFNa products, developing better routes of administration, etc.), the present invention provides a significant change in the direction of NMSC treatments: administering of IFNa-mRNA. IFNa-mRNA surprisingly does not lead to most of the adverse reaction observed for recombinant IFNa. The mRNA format of IFNa therefore provides a significant advantage over prior art therapy using IFNa protein. According to the present invention, following e.g. local and/or field-directed administration, IFNa mRNA will remain in the target cells and be expressed locally for several days at levels sufficient for the elimination of atypical keratinocytes without the need for bolus like application schedules and excessive dosing. This is impressively shown in the example section of the present invention. IFNa in vitro transcribed (IVT) mRNA according to the present invention is suited for the treatment of both, singular and multiple AK lesions depending primarily on the mode of administration, i.e. local versus field directed. Likewise, e.g. all 3 stages of AKs (Grade I-III) are targets for treatment with IFNa IVT mRNA according to the present invention.
The present invention also allows the use IFNa IVT mRNA as a minimally invasive, efficient local or field-directed therapy, with ideally a single application, building upon the sustainable expression of IVT mRNA in vivo. It is also evident that this strategy renders patient compliance irrelevant and increase treatment efficacy with higher responder rates than the current standard of care for AK and potentially for the direct treatment of SCC and BCC, respectively, especially those with IFNa protein that have been suggested more than 30 years ago. Other parameters including long-term recurrence rate and cosmetic outcome deserve consideration in the context of AK and NMSC and are also superior compared to current standard of care as well.
The mRNA used in the present invention contains (at least) five essential elements which are all known and available to a person skilled in the art (in this order from 5′ to 3′): a 5′ CAP region, a 5′ untranslated region (5′-UTR), a coding region for IFN-α, a 3′ untranslated region (3′-UTR) and a poly-adenosine tail (poly-A tail). The coding region should, of course encode a (human) IFN-α, the other components may be the (native) IFN-α UTRs or, preferably, other UTRs. Specifically preferred UTRs according to the present invention are UTRs which improve the properties of the mRNA molecule according to the present invention, i.e. by effecting better and/or longer and/or more effective translation of the mRNA into IFN-α protein at the site of administration.
A “CAP region” (“5′CAP”) refers to a structure found on the 5′ end of an mRNA molecule and generally consists of a guanosine nucleotide connected to the mRNA via an unusual 5′ to 5′ triphosphate linkage. This guanosine nucleotide is methylated on the 7-position directly after capping in vivo by a methyl transferase (“7-methylguanylate cap” (“m7G”), “cap-0”). Further modifications include the possible methylation of the 2′ hydroxy-groups of the first two ribose sugars of the 5′ end of the mRNA (i.e. “CAP1” and “CAP2”): “CAP1” has a methylated 2′-hydroxy group on the first ribose sugar, while “CAP2” has methylated 2′-hydroxy groups on the first two ribose sugars. The 5′ cap is chemically similar to the 3′ end of an RNA molecule (the 5′ carbon of the cap ribose is bonded, and the 3′ unbonded). This provides significant resistance to 5′ exonucleases and is therefore also providing stability in vivo. For generation of mRNAs according to the present invention also CAP analogues may be used including but not limited to: monomethylated CAP analogue (mCAP), Anti-Reverse Cap Analog (ARCA CAP), m7G(5′)ppp(5′)A RNA CAP structure analog, G(5′)ppp(5′)A RNA CAP structure analog, and G(5′)ppp(5′)G RNA CAP structure analog.
The term “(5′- or 3′-)UTR” refers to the well-established concept of untranslated region of a mRNA in molecular genetics. There is one UTR on each side of a coding sequence on a strand of mRNA. The UTR on the 5′ side, is the 5′-UTR (or leader sequence), the UTR on the 3′ side, is the 3′-UTR (or trailer sequence). The 5′-UTR is upstream from the coding sequence. Within the 5′-UTR is a sequence that is recognized by the ribosome which allows the ribosome to bind and initiate translation. The mechanism of translation initiation differs in prokaryotes and eukaryotes. The 3′-UTR is found immediately following the translation stop codon. The 3′-UTR plays a critical role in translation termination as well as post-transcriptional gene expression. The UTRs as used in the present invention are usually delivering beneficial stability and expression (translation) properties to the mRNA molecules according to the present invention. The 3′ end of the 3′-UTR also contains a tract of multiple adenosine monophosphates important for the nuclear export, translation, and stability of mRNA. This so-called poly-Adenosine (poly-A) tail consists of at least 60 adenosine monophosphates, preferably 100 and most preferably 120 adenosine monophosphates.
The “poly-A tail” consists of multiple adenosine monophosphates; it is a part of naturally occurring mRNA that has only adenine bases. This process called “polyadenylation” is part of the process that produces mature messenger RNA (mRNA) for translation in the course of gene expression. The natural process of polyadenylation begins as the transcription of a gene terminates. The 3′-most segment of the newly made pre-mRNA is first cleaved off by a set of proteins; these proteins then synthesize the poly(A) tail at the RNA's 3′ end. In some genes these proteins add a poly(A) tail at one of several possible sites. Therefore, polyadenylation can produce more than one transcript from a single gene (alternative polyadenylation), similar to alternative splicing. The poly(A) tail is important for the nuclear export, translation, and stability of mRNA. For the present invention it is therefore mainly the translation and stability properties that are important for a sufficient polyadenylation of the mRNA molecules according to the present invention. During the protein generation, the tail is shortened over time, and, when it is short enough, the mRNA is enzymatically degraded. The poly-A tail according to the present invention is provided in the manner currently used and applied in the art of administering mRNA molecules in human therapy. For example, the poly-A tail may be at least 60 adenosine monophosphates long. According to a preferred embodiment, the poly-A tail is at least 100 adenosine monophosphates long, especially at least 120 adenosine monophosphates. This allows excellent stability and protein generation; however, as for the other features, the action and activity of the mRNA molecule according to the present invention can also be regulated by the poly-A tail feature.
The sequences used in the mRNA molecules according to the present invention can either be native or not. This holds true for the IFN-α coding region as well as for the UTRs.
The term “native” relates to the human IFN-α mRNA in its natural environment.
Preferably, the sequences are not native but are improved to increase various parameters of the mRNA molecule, such as efficacy, stability, deliverability, producibility, translation initiation and translation.
For example, instead of using the native IFN-α coding sequence, sequences optimised with respect to GC-content or codon adaption index (CAI) may be used according to preferred embodiments of the present invention (see below).
The present invention, due to its mechanism, targets treatment and prevention of NMSC in general; actinic keratosis (AK), basal cell carcinoma (BCC) and squamous cell carcinoma (SCC) are, however, preferred indications addressed with the present invention, especially AK. The present invention allows administration of a powerful molecule (IFN-α encoding mRNA) in a very diligent manner so as to obtain a successful clinical outcome for the patients and at least a significant amelioration of disease, especially for AK. In case of AK, amelioration of disease is measured by assessing the number of lesion in a pre-defined area, typically the field of skin exposed to a comparable degree of carcinogen (mainly UV radiation). Lesion counts are done at baseline and at defined time points after the treatment, typically 1 and 3 months later. Response of individual lesions is assessed visually and by palpation. Parameters to be reported include mean reduction of lesion counts from baseline to assessment, rate of participants with a complete clearance of all lesions within a predefined field, rate of participants with at least a 75% reduction in AK lesion counts within a predefined field.
According to a preferred embodiment, the IFN-α mRNA according to the present invention is IFN-α type 1 mRNA (IFNa1), IFN-α type 2a mRNA (IFNa2a), or IFN-α type 2b mRNA (IFNa2b). These three types are the most straightforward IFN-α entities pursued by the present invention.
Since the major treatment/prevention area of the present invention is human medicine, the most preferred embodiment is, of course, a mRNA wherein the coding region encodes human IFN-α, especially human IFNa1, human IFNa2a, or human IFNa2b (as encoded by the various SEQ ID NOs disclosed in the example section of the present invention encoding IFN-α).
According to a preferred embodiment of the present invention, the present mRNA comprises in the 5′-UTR and/or 3′-UTR (preferably in the 3′UTR) one or more stabilisation sequences that are capable of increasing the half-life of the mRNA intracellularly. These stabilization sequences may exhibit a 100% sequence homology with naturally occurring sequences that are present in viruses, bacteria and eukaryotic cells, but may however also be partly or completely synthetic. Examples for such stabilizing sequences are described in: Nucleic Acids Res. 2010; 38 (Database issue): D75-D80. UTRdb and UTRsite (RELEASE 2010): a collection of sequences and regulatory motifs of the untranslated regions of eukaryotic mRNAs and under http://utrdb.ba.itb.cnr.it/.
As a further example of stabilising sequences that may be used in the present invention, the non-translated sequences (UTR) of the β-globin gene, for example of Homo sapiens or Xenopus laevis, may be mentioned.
Another example of a stabilisation sequence has been described in Holcik et al. (Proc. Natl. Acad. Sci. USA 1997, 94: 2410 to 2414) and has the general formula:
which is contained in the 3′UTR of the very stable mRNAs that code for example for alpha(1)-collagen or for alpha globin, and ALOX15 or for tyrosine hydroxylase (and wherein “x” is (independently in Nx and Pyx) an integer of 0 to 10, preferably of 0 to 5 (Holcik et al., 1997), especially 0, 1, 2, 4 and/or 5).
Such stabilisation sequences may be used individually or in combination with one another for stabilizing the inventive mRNA as well as in combination with other stabilisation sequences known to the person skilled in the art. E.g.: The stabilizing effect of human β-globin 3′-UTR sequences is further augmented by using two human β-globin 3′-UTRs arranged in a head-to-tail orientation.
Accordingly, a preferred embodiment of the IFN-α mRNA according to the present invention is an mRNA molecule, wherein the 5′-UTR or 3′-UTR or the 5′-UTR and the 3′-UTR are different from the native IFN-α mRNA, preferably wherein the 5′-UTR or 3′-UTR or the 5′-UTR and the 3′-UTR contain at least one a stabilisation sequence, preferably a stabilisation sequence with the general formula (C/U)CCANxCCC(U/A)PyxUC(C/U)CC (SEQ ID NO:38).
Preferably, the 5′-UTR and/or 3′-UTR are the 5′-UTR and/or 3′-UTR of a different human mRNA than IFN-α, preferably selected from alpha Globin, beta Globin, Albumin, Lipoxygenase, ALOX15, alpha(1) Collagen, Tyrosine Hydroxylase, ribosomal protein 32L, eukaryotic elongation factor 1a (EEF1A1), 5′-UTR element present in orthopoxvirus, and mixtures thereof, especially selected from alpha Globin, beta Globin, alpha(1) Collagen, and mixtures thereof.
Accordingly, the present invention preferably relates to an mRNA which comprises in the 3′-UTR one or more stabilisation sequences that are capable of increasing the half-life of the mRNA in the cytosol. These stabilisation sequences may exhibit a 100% sequence homology with naturally occurring sequences that are present in viruses, bacteria and eukaryotic cells, but may, however, also be partly or completely synthetic. As an example of stabilising sequences that may be used in the present invention, the non-translated sequences (UTR) of the β-globin gene, for example of Homo sapiens or Xenopus laevis, may be mentioned. As already stated, another example of a stabilisation sequence has the general formula (C/U)CCANxCCC(U/A)PyxUC(C/U)CC, which is contained in the 3′-UTR of the very stable mRNA that codes for alpha-globin, alpha-(1)-collagen, 15-lipoxygenase or for tyrosine hydroxylase (c.f. Holcik et al., Proc. Natl. Acad. Sci. USA 1997, 94: 2410 to 2414). Such stabilisation sequences may be used individually or in combination with one another for stabilizing the inventive modified mRNA as well as in combination with other stabilisation sequences known to the person skilled in the art.
Another preferred embodiment of the present invention is the 5′-TOP-UTR derived from the ribosomal protein 32L, followed by a stabilizing sequence derived from the albumin-3′-UTR.
Accordingly, a preferred embodiment of the IFN-α mRNA according to the present invention is an mRNA molecule containing a tract of multiple adenosine monophosphates at the 3′ end of the 3′-UTR. This so-called poly-adenosine (poly-A) tail consists of at least 60 adenosine monophosphates, preferably at least 100 and most preferably at least 120 adenosine monophosphates. Further stabilizing and translation efficient mRNAs are disclosed e.g. in WO 02/098443 A2 and EP 3 112 469 A1.
In certain cases, destabilizing the mRNA might be desirable as well to limit the duration of protein production. This effect can be achieved by incorporating destabilizing sequence elements (DSE) like AU-rich elements into 3′-UTRs, thus ensuring rapid mRNA degradation and a short duration of protein expression.
Although it may be desired for certain embodiments to provide an mRNA which is devoid of destabilizing sequence elements (DSE) in the 3′ and/or 5′ UTR, there may be other embodiments, wherein the presence or introduction of such DSEs is advantageous. In general, a “DSE” refers to a sequence, which reduces the half-life of a transcript, e.g. the half-life of the mRNA according to the present invention inside a cell and/or organism, e.g. a human patient. Accordingly, a DSE comprises a sequence of nucleotides, which reduces the intracellular half-life of an RNA transcript.
DSE sequences are found in short-lived mRNAs such as, for example: c-fos, c-jun, c-myc, GM-CSF, IL-3, TNF-alpha, IL-2, IL-6, IL-8, IL-10, Urokinase, bcl-2, SGL T1 (Na(+)-coupled glucose transporter), Cox-2 (cyclooxygenase 2), PAI-2 (plasminogen activator inhibitor type 2), beta(1)-adrenergic receptor or GAP43 (5′-UTR and 3′-UTR).
Further DSEs are AU-rich elements (AREs) and/or U-rich elements (UREs), including single, tandem or multiple or overlapping copies of the nonamer UUAUUUA(U/A)(U/A) (where U/A is either an A or a U) and/or the pentamer AUUUA and/or the tetramer AUUU. Further DSEs are described in Nucleic Acids Res. 2010; 38 (Database issue): D75-D80. UTRdb and UTRsite (RELEASE 2010): a collection of sequences and regulatory motifs of the untranslated regions of eukaryotic mRNAs and under http://utrdb.ba.itb.cnr.it/.
Accordingly, it may also be preferred if the 5′-UTR or 3′-UTR or the 5′-UTR and the 3′-UTR contain at least one destabilisation sequence element (DSE), preferably AU-rich elements (AREs) and/or U-rich elements (UREs), especially a single, tandem or multiple or overlapping copies of the nonamer UUAUUUA(U/A)(U/A), such as the pentamer AUUUA and/or the tetramer AUUU (the term “U/A” meaning either A or U).
These stabilizing and destabilizing elements can be used alone or in combination to aim at a given duration of protein production and to individualize the treatment of the present invention to the specific NMSC type, the specific stage of disease, the specific group of patients or even to the specific patient in a specific state of disease in this patient.
Although also nucleic acids encoding IFNa have been suggested for therapeutic applications, these proposals have either been suggested considerable time ago, were mostly related to DNA (not RNA or specifically mRNA) and were related to completely different fields and modes of administration. Moreover, the advantages revealed in the context of the present invention were not observed for these prior art uses of IFNa-mRNA. Treatment regimens comprising IFNa nucleic acids have primarily been used on liver diseases and viral diseases such as hepatitis C. WO 98/17801 A1 discloses a pharmaceutical composition for intravesical hepatoma treatment, whereby the composition comprises a recombinant adenoviral vector comprising a liver-specific promoter sequence and an IFNa-b encoding sequence. In a different approach described in WO 2006/134195 A2, IFNa DNA is administered as combination therapy together with either an IL-6 family, Gp130 family or ADN sequence for treating viral disease. Similar, WO 00/69913 A1 discusses a nucleic acid sequence or viral expression vector comprising a signal sequence, an immunoglobulin Fc region and a target protein sequence comprising IFNa, which is used for the treatment of hepatitis.
In the context of dermatological diseases, IFNa-DNA treatments have been applied to patients suffering from Condylomata acuminata (genital warts). In one approach the application WO/9000406 A1 described the combination of topical podophyllin treatment or an active constituent thereof together with intralesional injection of either recombinant human DNA IFN-2a or 2b in patients with Condylomata acuminata. In WO/9004977 A2 a combination therapy for the same disease disclosed intralesional injection of either recombinant human DNA IFN-2a or 2b following cryosurgical treatment with liquid nitrogen.
The use of immunostimulatory compositions comprising adjuvant mRNA complexed with a cationic or polycationic compound in combination with free mRNA encoding a tumour antigen has previously been described in WO 2010/037408 A1 for prophylaxis, treatment and/or amelioration of tumour diseases, autoimmune, infectious and allergic diseases. This approach allows efficient translation of the administered free mRNA into the protein of interest, while the mRNA complexed with the adjuvant component induces an immune response. WO 99/47678 A2 discloses the use of IFN-α plasmids for cancer treatment. Another approach to stabilize nucleic acid for in vivo application is the modification of nucleic acid sequence such as the addition of a Kunitz domain, a protease inhibitor (WO 2009/030464 A2).
RNA-based therapies for the treatment of rare dermatological diseases and treatments for use in medical dermatology, including AK, and aesthetic medicine have been suggested: WO 2015/117021 A1 discloses the use of a pharmaceutical composition comprising an RNA composed of one or more non-canonical nucleotides for the treatment of AK, whereby the nucleic acid encodes either for a protein of interest of the group of skin-specific structural or growth factor proteins, or for gene-editing protein targets. Similar, WO 2016/131052 A1 discusses the administration of RNA comprising non-canonical nucleotides encoding for either a protein of the family of interleukins, LIF, FGF growth factors, SERPINB1, caspase-1 or BMPs for treating diseases of the integumentary system including actinic keratosis. In both patent applications the administration of the pharmaceutical composition comprising the synthetic RNA can occur on multiple ways such as subcutaneous, intradermal, subdermal or intramuscular injection, as well as topical.
However, cytokines, such as interferons, especially IFNa, have not been suggested to be applied in this context.
General concepts for improved mRNA-based therapeutics (see e.g. Sahin et al., Nat. Rev. Drug Disc. 2014. 13(10): 759-780) are also applicable for the present invention.
For example, according to another preferred embodiment, the IFN-α mRNA according to the present invention may contain other residues than cytidine (C), uridine (U), adenosine (A) or guanosine (G) residues. There are a significant number of naturally occurring analogs of these nucleosides and also (even more) synthetic variants of these mRNA residues. Preferred embodiments of such variants can be found e.g. in WO 2014/153052 A2 and WO 2015/062738 A1.
According to a preferred embodiment, in the present IFN-α mRNA, at least 5%, preferably at least 10%, preferably at least 30%, especially at least 50% of all
Especially preferred embodiments are IFN-α mRNAs, wherein in the IFN-α mRNA, at least 5%, preferably at least 10%, preferably at least 30%, especially at least 50% of all
In the course of the present invention it has been surprisingly found out that even more improved results can be obtained if the GC-content (or GC to AU ratio) of the mRNA is further increased. The reason why this was specifically surprising was that the native IFNa sequences were already regarded as being optimal with respect to translation/expression efficiency. However, if the IFN-α mRNA according to the present invention is designed with a GC to AU ratio of at least 49.5% or more preferred at least 49.6% (e.g. at least 49.7, at least 49.8, at least 49.9), the performance according to the present invention further increases. Accordingly, the GC to AU ratio is preferably of at least 50%, more preferred, at least 55%, especially at least 60%.
In connection with the nucleoside variants disclosed above, it is important to note that the specific preferred variants described above do not influence the GC content, i.e. the variant is conservative in this respect (e.g. a cytidine variant still counts as a cytidine for the calculation of the GC content).
Another surprising observation revealed in the course of the present invention was the fact that IFNa-mRNAs with increased Codon Adaptation Index (CAI) also showed improved performance in the present invention, especially with respect to expression capacity within the cell.
The CAI is a measurement of the relative adaptiveness of the codon usage of a gene towards the codon usage of highly expressed genes. The relative adaptiveness (w) of each codon is the ratio of the usage of each codon, to that of the most abundant codon for the same amino acid. The CAI index is defined as the geometric mean of these relative adaptiveness values. Nonsynonymous codons and termination codons (dependent on genetic code) are excluded. CAI values range from 0 to 1, with higher values indicating a higher proportion of the most abundant codons (Sharp et al., Nucleic Acids Res. 15 (1987): 1281-1295, Jansen et al., Nucleic Acids Res. 31 (2003): 2242-2251).
Therefore, a preferred embodiment of the present invention relates to an IFN-α mRNA, wherein the IFN-α mRNA has a codon adaption index (CAI) of at least 0.8, preferably at least 0.81, at least 0.82, at least 0.83, at least 0.84, at least 0.85, at least 0.86, at least 0.87, at least 0.88, at least 0.89. Even a more preferred CAI of the mRNAs according to the present invention is at least 0.9, especially at least 0.91.
For comparison: native GC to AU ratio of IFNa1 is 49.5%, of IFNa2a is 48.7%, and of IFNa2b is 48.9%; native CAIs of IFNa1 is 0.8, of IFNa2a is 0.8, and of IFNa2b is 0.8.
Even more preferred, the mRNAs according to the present invention have a CAI of at least 0.8 AND a GC content of at least 49.5% (or an even more preferred higher CAI/GC content).
Preferred consensus sequences of the mRNA according to the present invention for IFNa2a are SEQ ID NOs:12, 13 and 14; most preferred SEQ ID NO:12.
SEQ ID NO:12 comprises GC rich sequences only; SEQ ID NO:13 is also optimised and includes AU rich sequences; SEQ ID NO:14 is an optimised sequence.
Accordingly, the coding region of the IFN-α mRNA encoding human IFNa2a is preferably SEQ ID NO:12, especially SEQ ID NOs: 2, 3, 5, 6, 7, 8, 9, 10, or 11; the coding region of the IFN-α mRNA encoding human IFNa2b is preferably SEQ ID NO:26, especially SEQ ID NOs: 19, 20, 22, or 25; the coding region of the IFN-α mRNA encoding human IFNa1 is preferably SEQ ID NO:36, especially SEQ ID NOs: 29, 30, 31, 32, 34, or 35.
Preferred embodiments of the present invention are IFN-α mRNAs which showed improved performance within the course of the present invention, specifically those molecules,
The present invention also relates to the mRNA molecules provided with the present invention (excluding the native RNA sequences and all mRNA sequences which comprise the native coding region of IFN-α).
According to a preferred embodiment, the IFN-α mRNA according to the present invention is administered subcutaneously, intradermally, transdermally, epidermally, or topically, especially epidermally.
Administration of the present IFN-α mRNA can be performed according to optimised expression aims, depending on the amount of mRNA applied, the stability of the mRNA molecule and the status of disease. For example, the IFN-α mRNA may be administered at least once, at least twice, at least twice within one month, preferably weekly. For example, if the IFN-α mRNA may be administered at least twice, at least twice within one month, preferably weekly doses applied may vary.
The amount of mRNA delivered per dose may also be made dependent on the stability of the molecule, etc. Preferably the IFN-α mRNA according to the present invention is administered in an amount of 0.001 μg to 100 mg per dose, preferably of 0.01 μg to 100 mg per dose, more preferably of 0.1 μg to 10 mg per dose, especially of 1 μg to 1 mg per dose.
Suitable formulations for mRNA therapeutics are well available in the art (see e.g. Sahin et al., 2014; WO 2014/153052 A2 (paragraphs 122 to 136), etc.).
The present invention therefore also relates to a pharmaceutical formulation comprising an IFN-α mRNA according to the present invention. The present formulation comprises the mRNA in a pharmaceutically acceptable environment, e.g. with suitable components usually provided in mRNA therapeutics (excipients, carriers, buffers, auxiliary substances (e.g. stabilizers), etc.)
The mRNA formulations according to the present invention preferably contain a suitable carrier. Suitable carriers include polymer based carriers, such as cationic polymers including linear and branched PEI and viromers, lipid nanoparticles and liposomes, nanoliposomes, ceramide-containing nanoliposomes, proteoliposomes, cationic amphiphilic lipids e.g: SAINT®-Lipids, both natural and synthetically-derived exosomes, natural, synthetic and semi-synthetic lamellar bodies, nanoparticulates, calcium phosphor-silicate nanoparticulates, calcium phosphate nanoparticulates, silicon dioxide nanoparticulates, nanocrystalline particulates, semiconductor nanoparticulates, dry powders, poly(D-arginine), nanodendrimers, starch-based delivery systems, micelles, emulsions, sol-gels, niosomes, plasmids, viruses, calcium phosphate nucleotides, aptamers, peptides, peptide conjugates, small-molecule targeted conjugates, and other vectorial tags. Also contemplated is the use of bionanocapsules and other viral capsid proteins assemblies as a suitable carrier. (Hum. Gene Ther. 2008 September; 19(9):887-95).
Preferred carriers are cationic polymers including linear and branched PEI and viromers, lipid nanoparticles and liposomes, transfersomes, and nanoparticulates including calcium phosphate nanoparticulates (i.e. naked RNA precipitated with CaCl2 and then administered).
A preferred embodiment of the present invention related to the use of non-complexed mRNA, i.e. non-complexed mRNA in a suitable aqueous buffer solution, preferably a physiological glucose buffered aqueous solution (physiological). For example, a 1×HEPES buffered solution; a 1× Phosphate buffered solution, Na-Citrate buffered solution; Na-Acetate buffered solution; preferred with Glucose (e.g.: 5% Glucose); physiologic solutions can be preferably applied.
Preferably the present invention applies liposomes, especially liposomes which are based on DOTAP, DOTMA, Dotap-DOPE, DOTAP-DSPE, Dotap-DSPE-PEG, Dotap-DOPE-PEG, Dotap-DSPE-PEG-Na-Cholate, Dotap-DOPE-PEG-Na-Cholate, DOTAP with cationic amphiphilic macromolecules (CAM) as complexes, and combinations thereof.
According to another aspect, the present invention relates to a kit for administering the IFN-α mRNA according to the present invention to a patient comprising
Preferably, the skin delivery device is
These administration devices are in principle available in the art; adaption to the administration of the mRNA according to the present invention is easily possible for a person skilled in the art.
The present invention also relates to a method for treating and preventing NMSC, preferably AK, BCC and SCC, wherein the mRNA according to the present invention is administered in an effective amount to a patient in need thereof.
According to a further aspect, the present invention also relates to the use of the mRNAs according to the present invention for the prevention or treatment of Condyloma and vascular deformities. Also for these aspects, the present invention is suitable.
In addition to NMSC (esp.: AK, BCC and SCC) also treatment of other skin conditions/diseases may be subject of the present invention. These conditions/diseases include but are not limited to vascular tumors and/or malformations such as hemangioma, and port-wine stains (nevus flammeus, firemark).
Superficial hemangiomas are situated higher in the skin and have a bright red, erythematous to reddish-purple appearance. Superficial lesions can be flat and telangiectatic, composed of a macule or patch of small, varied branching capillary blood vessels. They can also be raised and elevated from the skin, forming papules and confluent bright red plaques like raised islands. Superficial hemangiomas in certain locations, such as the posterior scalp, neck folds and groin/perianal areas are at potential risk of ulceration. Ulcerated hemangiomas can present as black crusted papules or plaques, or painful erosions or ulcers. Ulcerations are prone to secondary bacterial infections which can present with yellow crusting, drainage, pain or odor. Ulcerations are also at risk for bleeding, particularly deep lesions or in areas of friction. Multiple superficial hemangiomas, more than 5 can be associated with extracutaneous hemangiomas, the most common being a liver (hepatic) hemangioma and these warrant ultrasound examination.
Deep hemangiomas initially often present as poorly defined, bluish macules that can proliferate into papules, nodules or larger tumors. Proliferating lesions are often compressible, but fairly firm. Many deep hemangiomas may have a few superficial capillaries visible evident over the primary deep component or surrounding venous prominence. Deep hemangiomas have a tendency to develop a little later than superficial hemangiomas and may have longer and later proliferative phases as well. Deep hemangiomas rarely ulcerate, but can cause issues depending on their location, size and growth. Deep hemangiomas near sensitive structures can cause compression of softer surrounding structures during the proliferative phase, such as the external ear canal and the eyelid. Mixed hemangiomas are simply a combination of superficial and deep hemangiomas, and may not be evident for several months. Patients may have any combination of superficial, deep or mixed hemangiomas.
Treatment options for hemangiomas include medical therapies (systemic, intralesional and topical), surgery, and laser therapy. Prior to 2008, the mainstay of therapy for problematic hemangiomas was oral corticosteroids, which are effective and remain an option for patients in whom beta-blocker therapy is contraindicated or poorly tolerated. Following the serendipitous observation that propranolol, a non-selective beta blocker, is well tolerated and effective for treatment of hemangiomas, the agent was studied in a large, randomized controlled trial and was approved by the U.S. Food and Drug Administration for this indication in 2014. Propranolol has subsequently become the first-line systemic medical therapy for treatment of these lesions. Other systemic therapies which may be effective for hemangioma treatment include vincristine, interferon- and other agents with antiangiogenic properties. Vincristine, which requires central venous access for administration, is traditionally used as a chemotherapy agent, but has been demonstrated to have efficacy against hemangiomas and other childhood vascular tumors, such as Kaposiform hemangioendothelioma and tufted angioma. Interferon-alpha 2a and 2b, given via subcutaneous injection, has shown efficacy against hemangiomas (Wilson et al., Ophthalmology 2007; 114 (5): 1007-11), but may result in spastic diplegia in up to 20% of treated children (Barlow et al., J. Pediatr. 1998; 132(3 pt 1):527-30; and Worle et al., Eur. J. Pediatr. 1999; 158(4):344). Therefore, IFNa agents are rarely utilized now in the era of beta blocker therapy for hemangiomas.
The consensus sequences SEQ ID NOs:12, 13, 14, 26 and 36 are given with the following IUPAC nomenclature:
The invention is further explained by way of the following examples and the figures, yet without being limited thereto.
For transfection, murine 3T3 fibroblasts and human B.J. skin fibroblasts were seeded at 4-6×104 cells/well in 12-well plates. After 24 hours incubation in full EMEM or DMEM medium (Gibco, Thermo Fisher, USA), culture medium was replaced. Different formulations of IVT mRNA complexed with TransIT mRNA transfection reagent (Mirus Bio; complex formation according to manufacturer instructions) were prepared and added to the cells. 24 hours after transfection, medium was replaced with complete DMEM. The cells were further cultured under standard conditions for up to 5 days with daily medium changes until results evaluation.
Full-thickness porcine skin flaps were isolated peri-mortally from pigs (samples are obtained under full compliance to current national legislation (i.e. Tierversuchsgesetz 2012, TVG 2012)) and disinfected using Octenisept® disinfectant (Schuelke+Mayr GmbH, Germany).
Transfection of intact pig skin was done by direct, intradermal injection of the IVT-mRNA solution (1-10 μg mRNA/dose). LacZ IVTmRNA (completely modified using 5-methylcytidine, pseudouridine; Trilink Inc., USA) was formulated using either TransIT®-mRNA Transfection kit (Mirus Bio™) according to manufacturer instructions (with slight modification according to Kariko et al.; Mol. Ther. 2012. 20(5): 948-53) or DOTAP based liposomal formulations (Sigma Aldrich, USA). DOTAP based formulations were prepared using a lipid/RNA ratio of 5/1 (μg/μg). In addition, mRNA complexes were also supplemented with RNAse Inhibitor (5 U/dose, RNasin, Promega, USA). Injection volume was ranging from 20 μl to 30 μL.
Alternatively, transfection of intact pig skin was done by direct, intradermal injection of eGFP IVT-mRNA solution (0.5-25 μg mRNA/dose). eGFP IVTmRNA (AMPTec, Germany) was formulated using either TransIT®-mRNA Transfection kit (Mirus Bio™) according to manufacturer instructions (with slight modification according to Kariko et al., 2012, or DOTAP based liposomal formulations (Sigma Aldrich, USA), or Lipid-Nano-particle formulations (Polymun, Austria) or SAINT based liposomal formulations (Synvolux, Netherlands). DOTAP based liposomal formulations were prepared using a lipid/RNA ratio of 5/1 (μg/μg). SAINT lipid based formulations were prepared using a lipid/RNA ratio of 2.5-4/1 (μg/μg). In addition, also non-complexed mRNA in physiologic buffer was applied intradermally. Injection volume was ranging from 20 μl to 30 μL.
After injection punch biopsies of the injected areas (8 mm, diameter) were taken, subcutaneous fat was removed and biopsies were transferred into standard complete culture medium in a petridish, epidermis up (5 mL; containing: Dulbecco's Modified Eagle Medium with GlutaMAX (DMEM), 10% FCS, 1× Penicillin-Streptomycin-Fungizone; obtained from Gibco. Life Technologies). Subsequent culture was performed at 37° C./5% CO2 for 24 h. Harvest of biopsies was usually done 24 hours post transfection.
Full-thickness porcine skin flaps were isolated peri-mortally from pigs (samples are obtained under full compliance to current national legislation (i.e. Tierversuchsgesetz 2012, TVG 2012)) and disinfected using Octenisept® disinfectant (Schuelke+Mayr GmbH, Germany). Punch biopsies (6 or 8 mm, diameter) were taken from full-thickness skin flaps, subcutaneous fat was removed and biopsies were cut in two parts. Immediately afterwards cut biopsies were transferred, epidermis upside, to 9 cm (diameter) petri-dishes containing 5 mL Dispase II digestion solution (ca. 2.5 Units/mL; Dispase II; Sigma Aldrich, USA). Subsequent digestion was performed at 4° C. overnight. Dispase II digestion solution was prepared by diluting Dispase II stock solution (10 mg/mL in 50 mM HEPES/150 mM NaCl; pH-7.4) 1:2 with 1× DMEM (Gibco) and adding 1× Penicillin/Streptomycin. On the next day epidermal sheets were removed from the underlying dermis using forceps and transferred into DMEM for a short (5 min.) washing step. Subsequently sheets were put into complete DMEM culture medium and incubated at 37° C./5% CO2 (6 to 8 hours) until transfection was performed in 24-well culture plates. Transfection of porcine epidermal sheets was performed using eGFP IVTmRNA (AmpTec, Germany) or IVT mRNA constructs for IFNa (e.g.: SEQ ID NOs:1-5 and NO:53). mRNA was formulated using either TransIT®-mRNA Transfection kit (Mirus Bio™) according to manufacturer instructions or liposomal formulations (Polymun, Austria). Liposomal formulations were prepared using a lipid/RNA ratio of 5/1 (μg/μg). All lipoplex solutions for transfection contained 0.1 μg to 10 μg mRNA/mL DMEM medium and epidermal sheets were cultured one to three days.
For analysis, tissue culture supernatants were collected for subsequent ELISA analysis. Sheets were harvested for RNA and protein extraction and subsequent analysis by qPCR and ELISA, respectively. In addition, eGFP transfected epidermal sheets were also analysed for eGFP expression by direct fluorescence microscopy and immunohistochemistry detecting eGFP in situ.
RT-PCR Analysis of Cells Transfected Using IVT mRNA Preparations
Human B.J. cells and murine 3T3 fibroblasts were transfected using 0.1 to 1 μg IFNa2 IVT mRNAs complexed with TransIT mRNA transfection reagent. Total cellular RNAs were isolated from murine and human fibroblasts or porcine epithelial sheets at different time points post transfections using Tri-Reagent (Thermo Fisher, USA, manufacturer instructions) and mRNAs were reverse transcribed into cDNA by conventional RT-PCR (Protoscript First Strand cDNA synthesis kit, New England Biolabs, according to manufacturer instructions). cDNA samples were then subjected to conventional PCR and qPCR. Primers used were obtained from Invitrogen.
PCR analysis detecting IFNa2 variants was performed from cDNA obtained from cells/sheets transfected with different IFNa2 variants using Platinum Taq Polymerase (Invitrogen, USA) and IFNa2 variant specific primers (Invitrogen, USA). Human RPL4 and murine ACTB (Eurofins Genomics) were used as positive controls. PCR products were analysed using conventional agarose gel electrophoresis.
Analysis of IVT mRNA Induced Human IFNa2 Protein
Human B.J. cells and porcine epithelial sheets were transfected using 0.1-1 μg IVT mRNA for different IFNa2 variants complexed with TransIT mRNA transfection reagent and cultured for up to 120 h post transfection. Supernatant from transfected cells and epithelial sheets was obtained at several time points after transfection. Similarly, cells were harvested at the same time points and protein was extracted. Protein was extracted using cell extraction buffer (10 mM HEPES, 10 mM KCl, 0.1 μM EDTA, 0.3% NP40 and Roche Protease Inhibitor, according to manufacturer's protocol). IFN-α determination in supernatants as well cellular extracts was performed using the human IFN-α (subtype 2; IFNa2) ELISA development kit (MABTECH AB, Sweden, according to manufacturer instructions), measurements were taken on an Infinite 200 PRO multimode reader (Tecan AG, Switzerland).
Analysis of IVT mRNA Induced eGFP Protein
Intact porcine skin explants and porcine epithelial sheets were transfected using 0.1-10 μg eGFP IVT mRNA complexed with TransIT mRNA transfection reagent or different liposomal carriers or uncomplexed (“naked” in physiologic buffer) and cultured for 24 h post transfection. Samples were harvested and protein was extracted using cell extraction buffer (10 mM HEPES, 10 mM KCl, 0.1 μM EDTA, 0.3% NP40 and Roche Protease Inhibitor, according to manufacturer's protocol). eGFP determination was performed using the GFP in vitro SimpleStep ELISA® kit (Abcam Plc., UK, according to manufacturer instructions), measurements were taken on an Infinite 200 PRO multimode reader (Tecan AG, Switzerland).
Whole-mount beta-galactosidase (bGal) staining of biopsies was performed in 24 well culture plates for 24 or 48 h hours at 37° C. Positive staining controls were generated by injecting bGal enzyme (1 U recombinant bGal protein/injection) intradermally into pig skin. Before starting the staining procedure biopsies were mildly fixed in 4% formaldehyde solution (PBS) for 1 hour at room temperature. After fixation samples were washed in PBS (3×) and subsequently equilibrated in LacZ-washing buffer (2 mM MgCl2, 0.01% Na-deoxycholate and 0.02% NP-40 dissolved in PBS). After equilibration in LacZ buffer samples were stored overnight (4° C.). Subsequently samples were incubated in staining solution at 37° C. and colour reaction was monitored. The staining solution was freshly prepared (5 mM K4Fe(CN)6 and 5 mM K3Fe(CN)6 in LacZ buffer) and 1 mg/mL 5-Bromo-3-indolyl β-D-galactopyranoside, (Bluo-Gal) was added as colour substrate. If staining was performed for 48 hours the staining solution was substituted after 24 hours. Staining volume was generally 0.5 mL/well. Staining was stopped by washing in LacZ washing buffer and 3×PBS. Samples were subsequently either fixed overnight in buffered 4% formaldehyde solution and further processed for standard histology or were frozen in OCT for subsequent histologic analyses.
Full-thickness human skin flaps were obtained from standard esthetic and reconstructive surgical procedures (samples are obtained under full compliance to current national legislation) and disinfected using Octenisept® disinfectant (Schuelke+Mayr GmbH, Germany).
For biolistic mRNA transfection, the BioRad Helios gene gun system was used. The system was loaded with IVT mRNA coated gold particles (1.6 μm gold microcarriers loaded with 1 μg/μl IVT-mRNA; Biorad; according to manufacturer's protocols). Biolistic transfection was performed using helium gas pressure of 400 psi at a distance of 2.5 cm to human skin explants. Following transfection, punch biopsies of the transfected areas (8 mm, diameter) were taken, subcutaneous fat was removed and biopsies were transferred into standard complete culture medium in a petri dish, epidermis up. Biopsies were maintained in αMEM+10% pHPL media at an air-liquid interface at 5% CO2 for 24 hours. Harvest of biopsies was usually performed 24 hours post transfection.
Analysis of eGFP Protein In Situ in Human Skin
For biolistic transfection, the BioRad Helios Gene Gun System was used, loaded with eGFP-mRNA coated gold particles (1.6 μm gold microcarriers loaded with 1 μg/μl eGFP-mRNA) using a helium gas pressure of 400 psi at a distance of 2.5 cm to 8 mm human skin explants. Explants were maintained in αMEM+10% pHPL media at an air-liquid interface at 5% CO2 for 24 hours. Biopsies were fixed in 4% Paraformaldehyde over night at 4° C. and 10 μm cryosections were obtained. GFP antibody (Anti-GFP; chicken IgY) was used and detected by Alexa Fluor 488-conjugated donkey anti-chicken IgY antibody. The cytoskeleton was detected by staining F-actin using Alexa Fluor 568 Phalloidin and slides were mounted in Roti-mount Fluor Care DAPI containing DAPI (4′,6-Diamidin-2-phenylindol) for counterstaining. Slides were scanned in 20× magnification by the Olympus Slidescanner VS-120-L 100-W system. Scale Bar in (A,B)=500 μm; Scale Bar in (C-L)=50 μm
In Vivo Application of Firefly Luciferase IVT mRNA and Analysis of IVT mRNA Induced FLuc Protein
All animal experiments were exclusively being carried out at the University Clinic for Swine (University of Veterinary Medicine Vienna) and were performed in accordance with the Austrian Animal Experiments Act (TVG2012) using pigs (mixed breed; Edelschwein×Pietrain). Experiments were approved by the Committee on the Ethics of Animal Experiments of the University of Veterinary Medicine Vienna and the and the Austrian Federal Ministry of Education, Science and Research and were performed under approval number: GZ 68.205/0192-WF/V/3b/2017. Pigs were between 30 kg and 50 kg at the time of the start of the experiment. On the day prior to the planned injections, the flanks of all pigs are carefully shaved in order to avoid skin irritations as much as possible. On the day of the injections, the pigs are anesthetized. Prior to the injections, the shaved skin areas are thoroughly cleaned with warm water and disinfected twice with Octenisept (Schuelke+Mayr GmbH, Germany). For the intradermal injections 30 μL was applied using insulin syringes (BD MicroFine™+). The injection spots are distinctly marked with a suitable marker (Securline® Laboratory Markers) and labelled according to the injections scheme. For sample analysis, pigs were euthanized under deep anaesthesia 24 h and 48 h post injection by trained personnel. Skin flaps containing all injection spots were resected and put on ice immediately. Porcine skin biopsies from labeled areas were harvested using 10 mm punch biopsies. Samples were collected in 100 uL of Dulbecco's Modified Eagle Medium, DMEM, High Glucose (Gibco) in a white 96 well plate (MicroWell™, Nunc). Samples were subjected to direct Luciferase activity measurement. Measurements were performed using Firefly Luc One-Step Glow Assay Kit (Thermo Scientific, USA, according to manufacturer's instructions) and analysed on an Infinite 200 PRO multimode reader (Tecan AG, Switzerland).
In order to assess whether IFNa2 mRNA variants are stable in human skin fibroblasts over prolonged time periods, different mRNAs encoding SEQ ID NOs:1-5 were used to transfect B.J. cells. RNA was isolated at different time points (24-120 h post transfection) and the presence of mRNA in transfected cells was determined up to 120 h post transfection by non-quantitative RT PCR.
Result: As shown in
In order to assess whether codon optimization for optimal translation efficiency in the human system (as determined by the codon adaption index, CAI) and concomitant increase of GC content in the coding sequence (CDS) of IFNa2 mRNA variants changes expression of human IFNa2a protein in human skin fibroblasts, BJ fibroblasts were transfected with different IFNa2a mRNA variants. mRNAs encoding SEQ ID NOs:1, 2, 3 and 5 were used to transfect BJ cells. Subsequently, the level of secretion of human IFNa2a from transfected cells was determined for up to 120 h post transfection.
Result: All 4 IFNa2 mRNA variants are inducing high levels of human IFNa2a protein using 1 μg mRNA/well at all time points assessed (
Those sequences which were above the threshold of (CAI≥0.8 and GC content≥49.5%) were inducing significantly higher expression levels of IFNa2a at early and late stages indicating a surprisingly high benefit over wt, native sequences in the amplitude and longevity of expression.
In this example the effect of differential codon optimization for GC contents lower than the threshold (49.5%) and lower CAI levels (i.e. CAI<0.8) in the coding sequence (CDS) of IFNa2 mRNA variants was assessed. BJ fibroblasts were transfected with native (SEQ ID NO:1) as well as variants displaying CAIs<0.8 and/or GC contents<49.5% (e.g.: SEQ ID NO:4) as described above. Subsequently, the level of secretion of human IFNa2a from transfected cells was determined for up to 120 h post transfection.
Result: Both IFNa2 mRNA variants are inducing high levels of human IFNa2a protein using 1 μg mRNA/12 well at all time points assessed (
Thus, sequences which underwent optimization but were below the threshold of (CAI≥0.8 and GC content≥49.5%) were less efficient in inducing IFNa2a in human cells (the amplitude and longevity of expression).
In order to assess whether codon optimization for optimal translation efficiency in the human system (as determined by the codon adaption index, CAI) and concomitant increase of GC content in the coding sequence (CDS) of IFNa2 mRNA variants changes expression of human IFNa2a protein in porcine skin, epithelial sheets derived from porcine skin were transfected with different IFNa2a mRNA variants. mRNAs encoding SEQ ID NOs:1, 2, 3 and 5 were used to transfect epithelial sheets. TransIT alone as well as TransIT complexed to eGFP mRNA were used as controls. Subsequently, the level of secretion of human IFNa2a from transfected tissues was determined for up to 72 h post transfection.
Result: All 4 IFNa2 mRNA variants are inducing high levels of human IFNa2a protein using 1 μg mRNA/well at all time points assessed (
Those sequences which were above the threshold of (CAI≥0.8 and GC content≥49.5%) were inducing significantly higher expression levels of IFNa2a at early and late stages indicating a surprisingly high benefit over wt, native sequences in the amplitude and longevity of expression in an intact porcine tissue.
In this example the effect of differential codon optimization for GC contents lower than the threshold (49.5%) and lower CAI levels (i.e. CAI<0.8) in the coding sequence (CDS) of IFNa2 mRNA variants was assessed. Porcine epithelial sheets were transfected with native (SEQ ID NO:1) as well as variants displaying CAIs<0.8 and/or GC contents<49.5% (e.g.: SEQ ID NO:4) as described above. Again, TransIT alone as well as TransIT complexed to eGFP mRNA were used as controls. Subsequently, the level of secretion of human IFNa2a from transfected tissue was determined for up to 72 h post transfection.
Result: Both IFNa2 mRNA variants are inducing high levels of human IFNa2a protein using 1 μg mRNA/well at all time points assessed (
Thus, sequences which underwent optimization but were below the threshold of (CAI≥0.8 and GC content≥49.5%) were less efficient in inducing IFNa2a in porcine tissue (amplitude and longevity of expression).
In this example eGFP expression was monitored over time as a positive control for transfection efficacy of experiments performed in example 4+5, respectively.
Porcine epithelial sheets were transfected with TransIT and TransIT complexed with eGFP mRNA as described above. In addition, also a second formulation of TransIT and eGFP mRNA (i.e. 0.5 μg mRNA/well) was included as dosage control. Subsequently, eGFP protein expression in transfected tissue was monitored by direct fluorescence microscopy.
Result: similar levels of eGFP expression were detectable in both examples analysed indicating comparability of transfection efficacies in both experiments (
In this example eGFP expression induced by an alternative transfection formulation was monitored over time.
Porcine epithelial sheets were transfected with a liposome based formulation using two different eGFP mRNA concentrations (2 μg/ml and 10 μg/ml mRNA) as described above. Subsequently, eGFP protein expression in transfected tissue was monitored by direct fluorescence microscopy.
Result: eGFP expression was detectable in a dose dependent manner in this experiment (
In order to assess whether mRNA variants are able to transfect mammalian skin in situ, punch biopsies obtained from porcine skin were transfected with different LacZ mRNA formulations. In this example LacZ expression induced by intradermal transfection was monitored by whole mount β-Galactosidase staining 24 h post transfection.
Transfection of intact pig skin was done by direct, intradermal injection of the IVT-mRNA solution (5 μg mRNA/dose; +/−Rnase inhibitor). mRNA was formulated using DOTAP-liposomes. 24 h post transfection organ samples were subjected to whole mount β-Galactosidase (bGal) staining. Successful transfection is detectable by BluoGal staining in situ. Subsequently, punch biopsies of the injected areas (8 mm, diameter) were taken, subcutaneous fat was removed and biopsies were cultured for 24 h.
Result: LacZ expression was visualized by detection of bGal activity in transfected biopsies (
In order to assess whether mRNA variants are able to transfect mammalian skin in situ, punch biopsies obtained from porcine skin were transfected with different eGFP mRNA formulations. In this example eGFP expression induced by intradermal transfection was monitored by eGFP protein ELISA from tissue extracts obtained 24 h post transfection. Along these lines, different formulations of eGFP mRNA were produced and injected (see Table 6 for details).
Formulations used included: eGFP mRNA complexed with TransIT mRNA transfection reagent, eGFP mRNA complexed with DOTAP based liposomal preparations, eGFP mRNA complexed with SAINT lipid based liposomal preparations, eGFP mRNA containing Lipid nano particles and as non-complexed eGFP mRNA formulated in physiologic buffer.
Transfection of intact pig skin was done by direct, intradermal injection of the IVT-mRNA solutions (the eGFP IVTm RNA (1-25 μg mRNA/dose)). mRNA was formulated using TransIT mRNA transfection reagent, DOTAP based-liposomes, SAINT lipid based-liposomes, lipid nano particles or non-complexed mRNA in physiologic buffer. Subsequently, punch biopsies of the injected areas (8 mm, diameter) were taken, subcutaneous fat was removed, biopsies were cultured for 24 h and subsequently analysed for eGFP expression. 24 h post transfection organ samples were subjected to protein extraction and subsequent eGFP protein ELISA.
Result: eGFP expression was detectable by eGFP protein ELISA 24 h post injection. (
In order to assess whether IFNa2 mRNA variants are stable in murine fibroblasts over prolonged time periods, different mRNAs encoding SEQ ID NOs:1-5 were used to transfect 3T3 cells. RNA was isolated at different time points (24-120 h post transfection) and the presence of mRNA in transfected cells was determined up to 120 h post transfection by non-quantitative RT PCR.
Result: As shown in
In order to assess whether codon optimization for optimal translation efficiency in the human system (as determined by the codon adaption index, CAI) and concomitant increase of GC content in the coding sequence (CDS) of IFNa2 mRNA variants changes expression of human IFNa2a protein in human skin fibroblasts, 3T3 fibroblasts were transfected with different IFNa2a mRNA variants. mRNAs encoding SEQ ID NOs:1, 2, 3 and 5 were used to transfect 3T3 cells. Subsequently, the level of secretion of human IFNa2a from transfected cells was determined for up to 120 h post transfection.
Result: All 4 IFNa2 mRNA variants are inducing high levels of human IFNa2a protein using 1 μg mRNA/well at all time points assessed (
Those sequences which were above the threshold of (CAI≥0.8 and GC content≥49.5%) were inducing significantly higher expression levels of IFNa2a at early and late stages indicating a surprisingly high benefit over wt, native sequences in the amplitude and longevity of expression.
In this example the effect of differential codon optimization for GC contents lower than the threshold (49.5%) and lower CAI levels (i.e. CAI<0.8) in the coding sequence (CDS) of IFNa2 mRNA variants was assessed. 3T3 fibroblasts were transfected with native (SEQ ID NO:1) as well as variants displaying CAIs<0.8 and/or GC contents<49.5% (e.g.: SEQ ID NO:4) as described above. Subsequently, the level of secretion of human IFNa2a from transfected cells was determined for up to 120 h post transfection.
Result: Both IFNa2 mRNA variants are inducing high levels of human IFNa2a protein using 1 μg mRNA/12 well at all time points assessed (
Thus, sequences which underwent optimization but were below the threshold of (CAI≥0.8 and GC content≥49.5%) were less efficient in inducing IFNa2a in human cells (the amplitude and longevity of expression).
In order to assess whether codon optimization for optimal translation efficiency in the human system (as determined by the codon adaption index, CAI) and concomitant increase of GC content in the coding sequence (CDS) of IFNa2 mRNA variants changes expression of human IFNa2a protein in porcine skin, epithelial sheets derived from porcine skin were transfected with different IFNa2a mRNA variants. mRNAs encoding SEQ ID NOs:1, 2, 3 and 5 were used to transfect epithelial sheets. TransIT alone was used as control. Subsequently, the intracellular level of human IFNa2a from transfected tissues was determined for up to 72 h post transfection.
Result: All 4 IFNa2 mRNA variants are inducing high levels of human IFNa2a protein using 1 μg mRNA/well at all time points assessed (
Those sequences which were above the threshold of (CAI≥0.8 and GC content≥49.5%) were inducing significantly higher expression levels of IFNa2a at early and late stages indicating a surprisingly high benefit over wt, native sequences in the amplitude and longevity of expression in an intact porcine tissue.
In this example the effect of modified nucleotides (e.g.: pseudoU and m5C) on expression levels of IFNa2 mRNA variants is assessed. Porcine epithelial sheets are transfected with two forms of native (SEQ ID NO:1) IVT mRNA: one containing 100% replacement of Pseudo-U for U and 5mC for C and one w/o modified nucleotides as well as two forms of an IFNa variant (SEQ ID NO:3) displaying CAIs>0.8 and/or GC contents>49.5% (e.g.: one variant of SEQ ID NO:3 containing 100% replacement of Pseudo-U for U and 5mC for C and one w/o modified nucleotides) as described above. Again, TransIT alone as well as TransIT complexed to eGFP mRNA are used as controls. Subsequently, the level of secretion of human IFNa2a from transfected tissue is determined for 24 h post transfection.
Result: As shown in
Those sequences which are above the threshold of (CAI≥0.8 and GC content≥49.5%) are inducing significantly higher expression levels of IFNa2a at early and late stages indicating a surprisingly high benefit over wt, native sequences in the amplitude and longevity of expression in an intact porcine tissue.
In this example the effect of modified nucleotides (e.g.: pseudoU and m5C) on expression levels of IFNa2 mRNA variants is assessed. Human BJ fibroblasts are transfected with two forms of native (SEQ ID NO:1) IVT mRNA: one containing 100% replacement of Pseudo-U for U and 5mC for C and one w/o modified nucleotides as well as two forms of an IFNa variant (SEQ ID NO:3) displaying CAIs>0.8 and/or GC contents>49.5% (e.g.: one variant of SEQ ID NO:3 containing 100% replacement of Pseudo-U for U and 5mC for C and one w/o modified nucleotides) as described above. Again, TransIT alone as well as TransIT complexed to eGFP mRNA are used as controls. Subsequently, the level of secretion of human IFNa2a from transfected cells is determined for 24-120 h post transfection.
Result: As shown in
Those sequences which are above the threshold of (CAI≥0.8 and GC content≥49.5%) are inducing significantly higher expression levels of IFNa2a at early and late stages indicating a surprisingly high benefit over wt, native sequences in the amplitude and longevity of expression in an intact porcine tissue.
In this example the effect of UTR modification and differential codon optimization in the coding sequence (CDS) of IFNa2 mRNA variants was assessed.
Human BJ fibroblasts were transfected with fully human IFNa (SEQ ID NO:53), as well as IVT mRNAs containing the native IFNa coding sequence (CDS; SEQ ID NO:1). Again, TransIT alone as well as TransIT complexed to eGFP mRNA were used as controls (not shown). Subsequently, the level of secretion of human IFNa2a from transfected tissue was determined for up to 120 h post transfection.
Result: all IFNa2 mRNA variants used are inducing high levels of human IFNa2a protein using 1 μg mRNA/well at all time points assessed (
Thus, sequences which underwent UTR and/or CDS optimization were more efficient in inducing IFNa2a in porcine tissue (amplitude and longevity of expression) than the fully human IFNa mRNA. The extent of increase for SEQ ID NO:1 compared to SEQ ID NO:53 is: 6.2 fold at 24 h post transfection; 4.8 fold at 48 h post transfection; and 92.5 fold 72 h post transfection, respectively.
In this example the effect of UTR modification and differential codon optimization in the coding sequence (CDS) of IFNa2 mRNA variants was assessed.
Porcine epithelial sheets were transfected with fully human IFNa (SEQ ID NO:53), as well as IVT mRNAs containing the native IFNa coding sequence (CDS; SEQ ID NO:1) as well as CDS variants as described above (SEQ ID NO:3). Again, TransIT alone as well as TransIT complexed to eGFP mRNA were used as controls. Subsequently, the level of secretion of human IFNa2a from transfected tissue was determined for up to 48 h post transfection.
Result: all IFNa2 mRNA variants used are inducing high levels of human IFNa2a protein using 1 μg mRNA/well at all time points assessed (
Thus, sequences which underwent UTR and/or CDS optimization were more efficient in inducing IFNa2a in porcine tissue (amplitude and longevity of expression) than the fully human IFNa mRNA. The extent of increase compared to SEQ ID NO:53 is: 7.4 fold for SEQ ID NO:1; and 8.6 fold for SEQ ID NO:3, respectively.
In this example the effect of UTR modification and differential codon optimization in the coding sequence (CDS) of IFNa2 mRNA variants was assessed. Human skin biopsies from n=5 different donors were biolistically transfected using the Helios gene gun system with fully human IFNa (SEQ ID NO:53), as well as IVT mRNAs containing the native IFNa coding sequence (CDS; SEQ ID NO:1) or CDS variants as described above (SEQ ID NO:2, 3, 5). Non-transfected skin as well as skin transfected with eGFP IVT mRNA were used as controls. Subsequently, the level of secreted human IFNa2a from transfected tissue and the level of IFNa2a in tissue was determined for up to 24 h post transfection.
Result:
eGFP mRNA is inducing a very low level secretion of human IFNa2a from human skin following transfection (157 μg/ml; 12 fold lower than SEQ ID NO:53 (1873 μg/ml)). All IFNa2 mRNA variants used are inducing high levels of human IFNa2a protein secretion using 1 μg mRNA/μl loaded particles (
eGFP mRNA is inducing a very low level of human IFNa2a in human skin following transfection (44pg/mg tissue; 26 fold lower than SEQ ID NO:53 (1150pg/mg tissue)). All IFNa2 mRNA variants used are inducing high levels of human IFNa2a protein using 1 μg mRNA/μl loaded particles (
In this example the expression and localization of eGFP protein in human skin was assessed. Human skin biopsies from different donors were biolistically transfected using the Helios gene gun system with eGFP IVT mRNA. Skin treated with empty gold particles was used as control. Subsequently, biopsies were fixed 24 h post transfection in 4% Paraformaldehyde, and eGFP specific immunofluorescence analysis was performed on 10 μm cryosections.
Result: as shown in
In this example the effect of UTR modification and differential codon optimization in the coding sequence (CDS) of IFNa2 mRNA variants was assessed.
Porcine epithelial sheets were transfected with fully human IFNa (SEQ ID NO:53), as well as CDS variants as described above (SEQ ID NO: 4). Again, TransIT alone as well as TransIT complexed to eGFP mRNA were used as controls. Subsequently, the level of secreted human IFNa2a from transfected tissue was determined for up to 48 h post transfection.
Result: all IFNa2 mRNA variants used are inducing high levels of human IFNa2a protein using 1 μg mRNA/well at all time points assessed (
Thus, sequences which underwent UTR and/or CDS optimization were more efficient in inducing IFNa2a in porcine tissue (amplitude and longevity of expression) than the fully human IFNa mRNA.
In this example the effect of UTR modification and differential codon optimization in the coding sequence (CDS) of IFNa2 mRNA variants was assessed. Human skin biopsies from n=5 different donors were biolistically transfected using the Helios gene gun system with fully human IFNa (SEQ ID NO:53), as well as IVT mRNAs containing CDS variants as described above (SEQ ID NO:4). Non-transfected skin as well as skin transfected with eGFP IVT mRNA were used as controls. Subsequently, the level of secreted human IFNa2a from transfected tissue and the level of IFNa2a in tissue was determined for up to 24 h post transfection.
Result:
eGFP mRNA is inducing a very low level secretion of human IFNa2a from human skin following transfection (157 pg/ml; 12 fold lower than SEQ ID NO:53 (1873 pg/ml)). All IFNa2 mRNA variants used are inducing high levels of human IFNa2a protein secretion using 1 μg mRNA/μl loaded particles (
eGFP mRNA is inducing a very low level of human IFNa2a in human skin following transfection (44pg/mg tissue; 26 fold lower than SEQ ID NO:53 (1150pg/mg tissue)). All IFNa2 mRNA variants used are inducing high levels of human IFNa2a protein using 1 μg mRNA/μl loaded particles (
In this example, in vivo Firefly Luciferase (FLuc) expression induced by cationic polymer-based transfection formulations was monitored over time. For detection of Luciferase activity, pigs (ca. 45 kg, mixed breed; Edelschwein×Pietrain) were injected intradermally with Polymer based formulations using 2 different doses of mRNA: 1ng/μl (i.e.: 0.03 μg/dose) and 3.3ng/μl (i.e.: 0.1 μg/dose) mRNA as well as with non-complexed mRNA (3.3ng/μl; i.e.: 0.1 μg/dose) as described above. Native, non-transfected organ samples (i.e. skin biopsies) were used as background controls. Subsequently, Luciferase activity transfected tissue was monitored 24 h and 48 h post transfection by direct activity measurement. For analysis, injection sites were isolated and resulting biopsies were subjected to Firefly Luc One-Step Glow Assay Kit. Successful transfection was detectable by Bioluminescence (detection: relative luminescence units (RLU)).
Result: Luciferase activity was detectable using both doses of complexed FLuc mRNA following transfection (
Accordingly, the present invention relates to the following preferred embodiments:
1. Interferon alpha (IFN-α) messenger-RNA (mRNA), wherein the mRNA has a 5′ CAP region, a 5′ untranslated region (5′-UTR), a coding region encoding human IFN-α, a 3′ untranslated region (3′-UTR) and a poly-adenosine Tail (poly-A tail), for use in the prevention and treatment of non-melanoma skin cancer (NMSC) in a human patient.
2. IFN-α mRNA for use according to embodiment 1, wherein the NMSC is actinic keratosis (AK), basal cell carcinoma (BCC) and squamous cell carcinoma (SCC), especially AK.
3. IFN-α mRNA for use according to embodiment 1 or 2, wherein the IFN-α mRNA is selected from IFN-α type 1 mRNA (IFNa1), IFN-α type 2a mRNA (IFNa2a), and IFN-α type 2b mRNA (IFNa2b).
4. IFN-α mRNA for use according to any one of embodiments 1 to 3, wherein the poly-A tail comprises at least 100 adenosine monophosphates, preferably at least 120 adenosine monophosphates.
5. IFN-α mRNA for use according to any one of embodiments 1 to 4, wherein the 5′-UTR or 3′-UTR or the 5′-UTR and the 3′-UTR are different from the native IFN-α mRNA, preferably wherein the 5′-UTR or 3′-UTR or the 5′-UTR and the 3′-UTR contain at least one a stabilisation sequence, preferably a stabilisation sequence with the general formula (C/U)CCANxCCC(U/A)PyxUC(C/U)CC (SEQ ID NO:38), wherein “x” is, independently in Nx and Pyx, an integer of 0 to 10, preferably of 0 to 5, especially 0, 1, 2, 4 and/or 5).
6. IFN-α mRNA for use according to any one of embodiments 1 to 5, wherein the 5′-UTR or 3′-UTR or the 5′-UTR and the 3′-UTR are different from the native IFN-α mRNA, and contain at least one destabilisation sequence element (DSE), preferably AU-rich elements (AREs) and/or U-rich elements (UREs), especially a single, tandem or multiple or overlapping copies of the nonamer UUAUUUA(U/A)(U/A.
7. IFN-α mRNA for use according to any one of embodiments 1 to 6, wherein the 5′-UTR or 3′-UTR or the 5′-UTR and the 3′-UTR are different from the native IFN-α mRNA, and wherein the 5′-UTR and/or 3′-UTR are the 5′-UTR and/or 3′-UTR of a different human mRNA than IFN-α, preferably selected from alpha Globin, beta Globin, Albumin, Lipoxygenase, ALOX15, alpha(1) Collagen, Tyrosine Hydroxylase, ribosomal protein 32L, eukaryotic elongation factor 1a (EEF1A1), 5′-UTR element present in orthopoxvirus, and mixtures thereof, especially selected from alpha Globin, beta Globin, alpha(1) Collagen, and mixtures thereof.
8. IFN-α mRNA for use according to any one of embodiments 1 to 7, wherein in the IFN-α mRNA, at least 5%, preferably at least 10%, preferably at least 30%, especially at least 50% of all
Number | Date | Country | Kind |
---|---|---|---|
17164257.2 | Mar 2017 | EP | regional |
17200162.0 | Nov 2017 | EP | regional |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2018/058036 | 3/29/2018 | WO | 00 |