Obesity is a well-known risk factor for the development of many very common diseases such as atherosclerosis, hypertension, type 2 diabetes (non-insulin dependent diabetes mellitus (NIDDM)), dyslipidemia, coronary heart disease, and osteoarthritis and various malignancies. It also causes considerable problems through reduced motility and decreased quality of life. The incidence of obese people and thereby these diseases is increasing throughout the entire industrialized world. Accordingly, there is a great need to identify new methods to treat obesity.
In one aspect the present disclosure provides methods of treating an obesity-related disease, comprising administering to a subject in need thereof an effective amount of an inhibitor of MFSD7C or any one of its partners shown in
In another aspect the present disclosure provides methods of treating an obesity-related disease comprising administering to a subject in need thereof an effective amount of an activator of SERCA2b. Numerous embodiments are further provided that can be applied to any aspect of the present invention described herein. For example, in some embodiments, the activator of SERCA2b inhibits binding of MFSD7C to SERCA2b, results in uncoupled mitochondrial respiration, increases oxygen consumption rate and thermogenesis, or decreases mitochondrial membrane potential (MMP) and cellular ATP level. In some embodiments, the activator of SERCA2b is heme. In some embodiments, the obesity-related disease is obesity, atherosclerosis, hypertension, diabetes, type 2 diabetes, impaired glucose tolerance, dyslipidemia, coronary heart disease, gallbladder disease, osteoarthritis, or cancer. For example, the cancer is endometrial cancer, breast cancer, prostate cancer, or colon cancer.
In another aspect the present disclosure provides methods of identifying an inhibitor of MFSD7C, comprising contacting a cell with a candidate agent; measuring MFSD7C activity in the cell contacted with the candidate agent; and optionally comparing MFSD7C activity in the presence of the candidate agent with the MFSD7C activity in the absence of the candidate agent, wherein a decrease in MFSD7C activity in the presence of the candidate agent is indicative of inhibition of MFSD7C. Numerous embodiments are further provided that can be applied to any aspect of the present invention described herein. For example, in some embodiments, the inhibitor of MFSD7C or any one of its partners in
In another aspect the present disclosure provides methods of identifying an activator of SERCA2b, comprising: contacting a cell with a candidate agent; measuring SERCA2b activity in the cell contacted with the candidate agent; and optionally comparing the cell's SERCA2b activity in the presence of the candidate agent with the cell's SERCA2b activity in the absence of the candidate agent, wherein an increase in SERCA2b activity in the presence of the candidate agent is indicative of activation of SERCA2b. Numerous embodiments are further provided that can be applied to any aspect of the present invention described herein. For example, in some embodiments, the activator of SERCA2b inhibits binding of MFSD7C to SERCA2b, results in uncoupled mitochondrial respiration, increases oxygen consumption rate and thermogenesis, or decreases mitochondrial membrane potential (MMP) and cellular ATP level. In some embodiments, SERCA2b activity is measured using an ATP assay, a luciferase-based assay, a fluorescent-based assay, a β-galactosidase assay, flow cytometry, or a mitochondrial membrane potential assay. In some embodiments, SERCA2b activity is measured by a method selected from the group consisting of Western blotting, ELISA, and radioimmunoassay (RIA).
In one aspect the present disclosure provides methods of promoting weight gain comprising administering to a subject in need thereof an effective amount of an activator of MFSD7C or any one of its partners in
In another aspect the present disclosure provides methods of promoting weight gain comprising administering to a subject in need thereof an effective amount of an inhibitor of SERCA2b. Numerous embodiments are further provided that can be applied to any aspect of the present invention described herein. For example, in some embodiments, the inhibitor of SERCA2b promotes binding of MFSD7C to SERCA2b, results in coupled mitochondrial respiration, decreases oxygen consumption rate and thermogenesis, or increases mitochondrial membrane potential (MMP) and cellular ATP level. In some embodiments, the inhibitor of SERCA2b is a CRISPR based inhibitor, or siRNA. In some embodiments, the subject is a human or livestock, such as pig, cattle, chicken, turkey, lamb, or fish.
In another aspect the present disclosure provides methods of identifying an activator of MFSD7C, comprising contacting a cell with a candidate agent; measuring MFSD7C activity in the cell contacted with the candidate agent; and optionally comparing MFSD7C activity in the presence of the candidate agent with the MFSD7C activity in the absence of the candidate agent, wherein an increase in MFSD7C activity in the presence of the candidate agent is indicative of activation of MFSD7C. Numerous embodiments are further provided that can be applied to any aspect of the present invention described herein. For example, in some embodiments, the activator of MFSD7C promotes binding of MFSD7C to electron transport chain (ETC) components, such as mitochondrial complex III, IV, or V. In some embodiments, the activator of MFSD7C promotes binding of MFSD7C to SERCA2b, results in coupled mitochondrial respiration, decreases oxygen consumption rate and thermogenesis, or increases mitochondrial membrane potential (MMP) and cellular ATP level. In some embodiments, MFSD7C activity is measured using an ATP assay, a luciferase-based assay, a fluorescent-based assay, a β-galactosidase assay, flow cytometry, or mitochondrial membrane potential assay. In some embodiments, MFSD7C activity is measured by a method selected from the group consisting of Western blotting, ELISA, and radioimmunoassay (RIA).
In another aspect the present disclosure provides methods of identifying an inhibitor of SERCA2b, comprising: contacting a cell with a candidate agent; measuring SERCA2b activity in the cell contacted with the candidate agent; and optionally comparing the cell's SERCA2b activity in the presence of the candidate agent with the cell's SERCA2b activity in the absence of the candidate agent, wherein a decrease in SERCA2b activity in the presence of the candidate agent is indicative of inhibition of SERCA2b. Numerous embodiments are further provided that can be applied to any aspect of the present invention described herein. For example, in some embodiments, the inhibitor of SERCA2b promotes binding of MFSD7C to SERCA2b. In some embodiments, the inhibitor of SERCA2b results in coupled mitochondrial respiration, decreases oxygen consumption rate and thermogenesis, or increases mitochondrial membrane potential (MMP) and cellular ATP level. In some embodiments, SERCA2b activity is measured using an ATP assay, a luciferase-based assay, a fluorescent-based assay, a β-galactosidase assay, flow cytometry, or a mitochondrial membrane potential assay. In some embodiments, SERCA2b activity is measured by a method selected from the group consisting of Western blotting, ELISA, and radioimmunoassay (RIA).
ATP synthesis and thermogenesis are two critical outputs of mitochondrial respiration. How these outputs are regulated to balance the cellular requirement for energy and heat is largely unknown. Described herein is that major facilitator superfamily domain containing 7C (MFSD7C), a member of the 12-transmembrane solute carrier family, uncouples mitochondrial respiration to switch ATP synthesis to thermogenesis in response to heme. When heme levels are low, MSFD7C promotes ATP synthesis by interacting with components of the electron transport chain (ETC) complexes III, IV and V, and destabilizing sarcoendoplasmic reticulum Ca2+-ATPase 2b (SERCA2b). Upon heme binding to the N-terminal domain, MFSD7C dissociates from ETC components and SERCA2b, resulting in SERCA2b stabilization and thermogenesis. The novel heme-regulated switch between ATP synthesis and thermogenesis enables cells to match outputs of mitochondrial respiration to their metabolic state and nutrient supply, and represents a novel cell intrinsic mechanism to regulate mitochondrial energy metabolism.
Energy released from oxidation of carbohydrates and lipids generates a proton gradient across the mitochondrial inner membrane that can be used for ATP synthesis, thermogenesis, and transmembrane transport. While most attention has been focused on the role of mitochondrial respiration in ATP production, it is estimated that in endotherms majority of the proton-motive force is used for heat generation to maintain a stable body temperature. Uncoupling proteins UCP1, UCP2, and UCP3 are involved in cellular thermogenesis by transporting protons from the intermembrane space into the matrix of mitochondria. In particular, UCP1 is required for heat production by adipocytes of brown adipose tissue (BAT), where it is highly expressed. Apart from UCP1, Sarcoendoplasmic reticulum Ca2+-ATPase 2b (SERCA2b), which hydrolyzes ATP to pump Ca2+ from cytosol into the endoplasmic reticulum (ER) promotes thermogenesis in thermogenic organs of certain species of fish. SERCA2b was shown to be required for thermogenesis in beige adipocytes of UCP1−/− mice and in pigs, which lack a functional copy of Ucp1, while SERCA1 may stimulate thermogenic activity in white adipocytes in mice. Despite these findings, molecular mechanisms that regulate whether the energy stored in the mitochondrial proton gradient is used for ATP synthesis or thermogenesis to meet dynamic cellular requirements are largely unknown.
Heme, an iron-containing cyclic tetrapyrrole, belongs to an ancient class of co-factors that support diverse cellular processes. Heme is a co-factor for proteins involved in O2 and CO2 transport, mitochondrial respiration, redox reactions, circadian rhythm, transcription and translation. Particularly relevant to energy metabolism, heme is a co-factor for several electron transport chain (ETC) components, where it mediates electron transfer reactions that are coupled to formation of the mitochondrial proton gradients. These observations highlight the critical function of heme in energy metabolism, but whether it plays any role in regulating mitochondrial respiration has not been examined.
Major facilitator superfamily domain containing 7C (MFSD7C), also known as feline leukemia virus subgroup C receptor-related protein 2 (FLVCR2) and solute carrier family 49 member 2 (SLC49A2), is a member of the 12-transmembrane solute carrier family, implicated in proliferative vasculopathy and hydranencephaly-hydrocephaly or Fowler syndrome. Truncation and missense mutations in Mfsd7c are associated with this autosomal recessive prenatal lethal disorder characterized by multi-organ defects involving brain, kidney and muscle. MFSD7C was reported to be a heme transporter based on its binding to heme-conjugated agarose beads and the increased heme uptake by MFSD7C-transfected cells, however a direct role in heme transport has been questioned. To date, the cellular function of MFSD7C and the mechanism by which its mutations cause Fowler syndrome are unknown.
The cellular function of MFSD7C described herein is: i) MFSD7C resides in the mitochondria and interacts with components of ETC complexes III, IV and V as well as SERCA2b. ii) Knockout of Mfsd7c results in uncoupled mitochondrial respiration characterized by increased oxygen consumption rate (OCR) and thermogenesis, a phenotype that is phenocopied by treating parental cells with heme. iii) The knockout phenotype is corrected by expression of both a full-length and an N-terminal domain (NTD)-truncated MFSD7C, but only the former corrects response to heme. iv) Mechanistically, binding of heme to the NTD dissociates MFSD7C from ETC components and SERCA2b, leading to stabilization of SERCA2b and increased cellular thermogenesis. Our study identifies that MFSD7C switches ATP synthesis and thermogenesis in response to heme, therefore linking the outputs of mitochondrial respiration to the cell's metabolic state and nutrient supply.
MFSD7C is identified as a heme-regulated switch that controls coupling of mitochondrial respiration. Biochemical analyses support MFSD7C interacting with heme, components of ETC complexes, and SERCA2b. At least for the recombinant NTD, the findings are consistent with three molecules of heme binding, two with high affinity and one with much lower affinity, consistent with the NTD of human MFSD7C containing two and half heme-binding HP motifs. The fact that only five proteins from the ETC complexes were co-precipitated with MFSD7C in the proteomic analysis suggests there is selectivity of MFSD7C interactions with ETC components. The data suggest that MFSD7C interacts with SERCA2b at the mitochondrial-ER contact junction. Importantly, MFSD7C interactions with ETC components and SERCA2b are disrupted by heme and in particular heme stabilizes SERCA2b, which is ubiquitinated and degraded in the presence of MFSD7C. These dynamic interactions shed light on the mechanism by which MFSD7C regulates coupling of mitochondrial respiration in response to heme: when heme levels are low, MSFD7C interacts with ETC components and SERCA2b, leading to SERCA2b degradation and coupled mitochondrial respiration; upon binding of heme to the N-terminal domain of MFSD7C the interactions are disrupted, leading to the stabilization of SERCA2b and uncoupled mitochondrial respiration (
The Examples herein suggest heme is an endogenous metabolite that is sensed by MFSD7C to regulate mitochondrial respiration. The observation that the NTD of MFSD7C binds to 2-3 heme molecules could enable MFSD7C to respond to a range of heme concentrations. As a metabolite, heme is well suited as a proxy for monitoring the metabolic state and nutrient supply of the cell. First, heme is a co-factor for several ETC components and directly mediates electron transport reactions so that the mitochondrial heme level likely reflects the ETC capacity. Second, heme biosynthesis starts and finishes in the lumen of mitochondria. The rate limiting first step uses succinyl-CoA and glycine, which are, respectively, intermediates of tricarboxylic acid cycle and one-carbon metabolism, two important outputs of mitochondrial metabolism. The level of heme therefore reflects the metabolic state of the cell. Third, heme contains an iron and may reflect iron availability, and because it is absorbed from food, it might also reflect nutritional status at the organismal level. In fact, increased thermogenesis after a meal has been known since ancient times and food has been classified based on their thermogenic properties. Not surprisingly, meat, especially heme-abundant red meat, is the most thermogenic. However, the molecular basis underlying the thermic effect of food is largely unknown. Our findings suggest a possible new mechanism: heme absorbed from food stimulates thermogenesis by uncoupling mitochondrial respiration. Thus, the MFSD7C-mediated switch between ATP synthesis and thermogenesis in response to heme links the outputs of mitochondrial respiration to the cell's metabolic state and nutrient supply.
Our findings shed light on how dysfunctional mutations in Mfsd7c may cause Fowler syndrome. Accumulating evidence suggests that defects in energy metabolism play a critical role in neurodegeneration. For example, the late-onset Alzheimer' s disease is associated with rare variants of TREM2. TREM2-deficient microglia exhibit impaired mTOR activation and phagocytosis, which can be corrected with provision of an ATP precursor cyclocreatine. Similarly, DNAJC30 interacts with ATP6, a component of ATP synthase, and its mutation leads to reduced ATP production and William syndrome. Consistent with our findings, Castro-Gago et al. reported defects in ETC complexes III and IV in three patients from the same family with Fowler syndrome. It is possible that reduced ATP synthesis and increased thermogenesis due to dysfunctional mutations in Mfsd7c could induce chronic cellular stress and compromise neuronal cell survival. Identification of MFSD7C as a heme-regulated switch between ATP synthesis and thermogenesis provides a basis to test this hypothesis.
Our study raises many new questions for future investigation. First, we show that MFSD7C predominantly resides in the mitochondria by subcellular fractionation and confocal microscopy, but whether it resides in the inner or outer mitochondrial membrane is currently unknown. This is an important question because the orientation of MFSD7C on the inner or outer membrane determines whether it senses heme in the lumen of mitochondria or in the cytosol. If MFSD7C resides in the inner membrane, MFSD7C likely senses heme in the lumen of mitochondria (
In one aspect the present disclosure provides methods of treating an obesity-related disease comprising administering to a subject in need thereof an effective amount of an inhibitor of MFSD7C or any one of its partners in
In another aspect the present disclosure provides methods of treating an obesity-related disease comprising administering to a subject in need thereof an effective amount of an activator of SERCA2b.
In another aspect the present disclosure provides methods of identifying an inhibitor of MFSD7C, comprising contacting a cell with a candidate agent; measuring MFSD7C activity in the cell contacted with the candidate agent; and comparing MF SD7C activity in the presence of the candidate agent with the MFSD7C activity in the absence of the candidate agent, wherein a decrease in MFSD7C activity in the presence of the candidate agent is indicative of an inhibitor of MFSD7C.
In another aspect the present disclosure provides methods of identifying an activator of SERCA2b, comprising: contacting a cell with a candidate agent; measuring SERCA2b activity in the cell contacted with the candidate agent; and comparing SERCA2b activity in the presence of the candidate agent with the SERCA2b activity in the absence of the candidate agent, wherein an increase in SERCA2b activity in the presence of the candidate agent is indicative of an activator of SERCA2b.
In one aspect the present disclosure provides methods of promoting weight gain comprising administering to a subject in need thereof an effective amount of an activator of MFSD7C or any one of its partners in
In another aspect the present disclosure provides methods of promoting weight gain comprising administering to a subject in need thereof an effective amount of an inhibitor of SERCA2b.
In another aspect the present disclosure provides methods of identifying an activator of MFSD7C, comprising contacting a cell with a candidate agent; measuring MFSD7C activity in the cell contacted with the candidate agent; and optionally comparing MFSD7C activity in the presence of the candidate agent with the MFSD7C activity in the absence of the candidate agent, wherein an increase in MFSD7C activity in the presence of the candidate agent is indicative of activation of MFSD7C.
In another aspect the present disclosure provides methods of identifying an inhibitor of SERCA2b, comprising: contacting a cell with a candidate agent; measuring SERCA2b activity in the cell contacted with the candidate agent; and optionally comparing the cell's SERCA2b activity in the presence of the candidate agent with the cell's SERCA2b activity in the absence of the candidate agent, wherein a decrease in SERCA2b activity in the presence of the candidate agent is indicative of inhibition of SERCA2b.
Unless otherwise defined herein, scientific and technical terms used in this application shall have the meanings that are commonly understood by those of ordinary skill in the art. Generally, nomenclature used in connection with, and techniques of, chemistry, cell and tissue culture, molecular biology, cell and cancer biology, neurobiology, neurochemistry, virology, immunology, microbiology, pharmacology, genetics and protein and nucleic acid chemistry, described herein, are those well-known and commonly used in the art.
The methods and techniques of the present disclosure are generally performed, unless otherwise indicated, according to conventional methods well known in the art and as described in various general and more specific references that are cited and discussed throughout this specification. See, e.g. “Principles of Neural Science”, McGraw-Hill Medical, New York, N.Y. (2000); Motulsky, “Intuitive Biostatistics”, Oxford University Press, Inc. (1995); Lodish et al., “Molecular Cell Biology, 4th ed.”, W. H. Freeman & Co., New York (2000); Griffiths et al., “Introduction to Genetic Analysis, 7th ed.”, W. H. Freeman & Co., N.Y. (1999); and Gilbert et al., “Developmental Biology, 6th ed.”, Sinauer Associates, Inc., Sunderland, MA (2000).
The term “agent” is used herein to denote a chemical compound (such as an organic or inorganic compound, a mixture of chemical compounds), a biological macromolecule (such as a nucleic acid, an antibody, including parts thereof as well as humanized, chimeric and human antibodies and monoclonal antibodies, a protein or portion thereof, e.g., a peptide, a lipid, a carbohydrate), or an extract made from biological materials such as bacteria, plants, fungi, or animal (particularly mammalian) cells or tissues. Agents include, for example, agents whose structure is known, and those whose structure is not known.
The terms “decrease”, “reduced”, “reduction”, or “inhibit” are all used herein to mean a decrease by a statistically significant amount. In some embodiments, “reduce,” “reduction” or “decrease” or “inhibit” typically means a decrease by at least 10% as compared to a reference level (e.g., the absence of a given ligand) and can include, for example, a decrease by at least about 10%, at least about 20%, at least about 25%, at least about 30%, at least about 35%, at least about 40%, at least about 45%, at least about 50%, at least about 55%, at least about 60%, at least about 65%, at least about 70%, at least about 75%, at least about 80%, at least about 85%, at least about 90%, at least about 95%, at least about 98%, at least about 99%, or more. As used herein, “reduction” or “inhibition” does not encompass a complete inhibition or reduction as compared to a reference level. “Complete inhibition” is a 100% inhibition as compared to a reference level.
The terms “increased”, “increase” or “enhance” or “activate” are all used herein to generally mean an increase by a statically significant amount; for the avoidance of any doubt, the terms “increased”, “increase” or “enhance” or “activate” means an increase of at least 10% as compared to a reference level, for example an increase of at least about 20%, or at least about 30%, or at least about 40%, or at least about 50%, or at least about 60%, or at least about 70%, or at least about 80%, or at least about 90% or up to and including a 100% increase or any increase between 10-100% as compared to a reference level, or at least about a 2-fold, or at least about a 3-fold, or at least about a 4-fold, or at least about a 5-fold or at least about a 10-fold increase, at least about a 20-fold increase, at least about a 50-fold increase, at least about a 100-fold increase, at least about a 1000-fold increase or more as compared to a reference level.
A “patient,” “subject,” or “individual” are used interchangeably and refer to either a human or a non-human animal. These terms include mammals, such as humans, primates, livestock animals (including bovines, porcines, etc.), companion animals (e.g., canines, felines, etc.) and rodents (e.g., mice and rats).
“Treating” a condition or patient refers to taking steps to obtain beneficial or desired results, including clinical results. As used herein, and as well understood in the art, “treatment” is an approach for obtaining beneficial or desired results, including clinical results. Beneficial or desired clinical results can include, but are not limited to, alleviation or amelioration of one or more symptoms or conditions, diminishment of extent of disease, stabilized (i.e. not worsening) state of disease, preventing spread of disease, delay or slowing of disease progression, amelioration or palliation of the disease state, and remission (whether partial or total), whether detectable or undetectable. “Treatment” can also mean prolonging survival as compared to expected survival if not receiving treatment.
The term “preventing” is art-recognized, and when used in relation to a condition, such as a local recurrence (e.g., pain), a disease such as cancer, a syndrome complex such as heart failure or any other medical condition, is well understood in the art, and includes administration of a composition which reduces the frequency of, or delays the onset of, symptoms of a medical condition in a subject relative to a subject which does not receive the composition. Thus, prevention of cancer includes, for example, reducing the number of detectable cancerous growths in a population of patients receiving a prophylactic treatment relative to an untreated control population, and/or delaying the appearance of detectable cancerous growths in a treated population versus an untreated control population, e.g., by a statistically and/or clinically significant amount.
“Administering” or “administration of” a substance, a compound or an agent to a subject can be carried out using one of a variety of methods known to those skilled in the art. For example, a compound or an agent can be administered, intravenously, arterially, intradermally, intramuscularly, intraperitoneally, subcutaneously, ocularly, sublingually, orally (by ingestion), intranasally (by inhalation), intraspinally, intracerebrally, and transdermally (by absorption, e.g., through a skin duct). A compound or agent can also appropriately be introduced by rechargeable or biodegradable polymeric devices or other devices, e.g., patches and pumps, or formulations, which provide for the extended, slow or controlled release of the compound or agent. Administering can also be performed, for example, once, a plurality of times, and/or over one or more extended periods.
Appropriate methods of administering a substance, a compound or an agent to a subject will also depend, for example, on the age and/or the physical condition of the subject and the chemical and biological properties of the compound or agent (e.g., solubility, digestibility, bioavailability, stability and toxicity). In some embodiments, a compound or an agent is administered orally, e.g., to a subject by ingestion. In some embodiments, the orally administered compound or agent is in an extended release or slow release formulation, or administered using a device for such slow or extended release.
A “therapeutically effective amount” or a “therapeutically effective dose” of a drug or agent is an amount of a drug or an agent that, when administered to a subject will have the intended therapeutic effect. The full therapeutic effect does not necessarily occur by administration of one dose, and may occur only after administration of a series of doses. Thus, a therapeutically effective amount may be administered in one or more administrations. The precise effective amount needed for a subject will depend upon, for example, the subject's size, health and age, and the nature and extent of the condition being treated, such as cancer or MDS. The skilled worker can readily determine the effective amount for a given situation by routine experimentation.
The present disclosure provides methods of identifying an inhibitor of MFSD7C, comprising contacting a cell with a candidate agent; measuring MFSD7C activity in the cell contacted with the candidate agent; and optionally comparing the cell's MFSD7C activity in the presence of the candidate agent with the cell's MFSD7C activity in the absence of the candidate agent, wherein a decrease in MFSD7C activity in the presence of the candidate agent is indicative of inhibition of MFSD7C.
In another aspect the present disclosure provides methods of identifying an activator of SERCA2b, comprising: contacting a cell with a candidate agent; measuring SERCA2b activity in the cell contacted with the candidate agent; and optionally comparing the cell's SERCA2b activity in the presence of the candidate agent with the cell's SERCA2b activity in the absence of the candidate agent, wherein an increase in SERCA2b activity in the presence of the candidate agent is indicative of activation of SERCA2b.
As used herein, the term “test compound” or “candidate agent” refers to an agent or collection of agents (e.g., compounds) that are to be screened for their ability to have an effect on the cell. Test compounds can include a wide variety of different compounds, including chemical compounds, mixtures of chemical compounds, e.g., polysaccharides, small organic or inorganic molecules (e.g., molecules having a molecular weight less than 2000 Daltons, less than 1000 Daltons, less than 1500 Dalton, less than 1000 Daltons, or less than 500 Daltons), biological macromolecules, e.g., peptides, proteins, peptide analogs, and analogs and derivatives thereof, peptidomimetics, nucleic acids, nucleic acid analogs and derivatives, an extract made from biological materials such as bacteria, plants, fungi, or animal cells or tissues, naturally occurring or synthetic compositions.
Depending upon the particular embodiment being practiced, the test compounds can be provided free in solution, or can be attached to a carrier, or a solid support, e.g., beads. A number of suitable solid supports can be employed for immobilization of the test compounds. Examples of suitable solid supports include agarose, cellulose, dextran (commercially available as, i.e., Sephadex, Sepharose) carboxymethyl cellulose, polystyrene, polyethylene glycol (PEG), filter paper, nitrocellulose, ion exchange resins, plastic films, polyaminemethylvinylether maleic acid copolymer, glass beads, amino acid copolymer, ethylene-maleic acid copolymer, nylon, silk, etc. Additionally, for the methods described herein, test compounds can be screened individually, or in groups. Group screening is particularly useful where hit rates for effective test compounds are expected to be low such that one would not expect more than one positive result for a given group.
A number of small molecule libraries are known in the art and commercially available. These small molecule libraries can be screened using the screening methods described herein. A chemical library or compound library is a collection of stored chemicals that can be used in conjunction with the methods described herein to screen candidate agents for a particular effect. A chemical library comprises information regarding the chemical structure, purity, quantity, and physiochemical characteristics of each compound. Compound libraries can be obtained commercially, for example, from Enzo Life Sciences™, Aurora Fine Chemicals™, Exclusive Chemistry Ltd.™, ChemDiv, ChemBridge™, TimTec Inc.™, AsisChem™, and Princeton Biomolecular Research™, among others.
Without limitation, the compounds can be tested at any concentration that can exert an effect on the cells relative to a control over an appropriate time period. In some embodiments, compounds are tested at concentrations in the range of about 0.01 nM to about 100 nM, about 0.1 nM to about 500 microM, about 0.1 microM to about 20 microM, about 0.1 microM to about 10 microM, or about 0.1 microM to about 5 microM.
The compound screening assay can be used in a high throughput screen. High throughput screening is a process in which libraries of compounds are tested for a given activity. High throughput screening seeks to screen large numbers of compounds rapidly and in parallel. For example, using microtiter plates and automated assay equipment, a laboratory can perform as many as 100,000 assays per day, or more, in parallel.
The compound screening assays described herein can involve more than one measurement of the cell or reporter function (e.g., measurement of more than one parameter and/or measurement of one or more parameters at multiple points over the course of the assay). Multiple measurements can allow for following the biological activity over incubation time with the test compound. In one embodiment, the reporter function is measured at a plurality of times to allow monitoring of the effects of the test compound at different incubation times.
The screening assay can be followed by a subsequent assay to further identify whether the identified test compound has properties desirable for the intended use. For example, the screening assay can be followed by a second assay selected from the group consisting of measurement of any of: bioavailability, toxicity, or pharmacokinetics, but is not limited to these methods.
The invention now being generally described, it will be more readily understood by reference to the following examples which are included merely for purposes of illustration of certain aspects and embodiments of the present invention, and are not intended to limit the invention.
Purification of MFSD7C N-terminal domain (NTD). Plasmid harboring GST-His-tag-SUMO-NTD (amino acids 1-84) was transformed into Escherichia coli Lemo21(DE3) strain (New England Biolabs), and grown overnight in 50 mL of LB supplemented with ampicillin (100 μg/mL) at 37° C. The following day, 5 mL of overnight culture was diluted in 5 L of terrific broth media (TB) supplemented with ampicillin (100 μg/mL) at 37° C. and grown to O.D.600=0.6. The expression of GST-His-tag-SUMO-NTD was induced with 0.5 mM IPTG for 16 hours at 37° C. Cells were harvested by centrifugation and washed once with ice-cold Milli-Q water. The washed pellet was resuspended in 50 mL of ice-cold buffer A (50 mM Tris-HCl pH 8.0, 500 mM NaCl, 0.5% Triton X-100) containing Protease Inhibitor Cocktail VII (RPI International), and the resuspension was frozen at −80° C. for no longer than one week. The resuspension was thawed at room temperature, and cells were lysed by sonication in the cold room. The lysate was cleared by centrifugation (20,000 g for 45 min) and the supernatant was incubated with 5 mL of Complete His-tag Purification Resin (Roche) pre-equilibrated with buffer A for 3 hours while rotating in the cold room. The flow-through was discarded and the resin was washed twice with 25 mL of ice-cold buffer B (10 mM Tris-HCl pH 8.0, 100 mM NaCl). GST-His-tag-SUMO-NTD was eluted from the resin with 20 mL of buffer B containing 300 mM imidazole. Eluted fraction was supplemented with β-mercaptoethanol (f.c. 2 mM), and NTD was cleaved off from the rest of the protein with catalytic subunit of yeast Ulp1 (f.c. 1 μg/mL for 1 hour in the cold room). After incubation with Ulp1, the mixture was flash-frozen in liquid nitrogen, lyophilized overnight, and resuspended in 10 mL of pure HPLC-grade water. This step eliminated volatile molecules such as β-mercaptoethanol, and selectively precipitated GST-His-tag-SUMO, Ulp1, and other contaminating proteins while it had no effect on the stability of water-soluble and intrinsically disordered NTD. Precipitate was cleared by centrifugation (20,000 g for 15 min) and the supernatant containing the NTD was transferred to fresh tubes. NTD was precipitated with isopropanol (f.c. 50% v/v) at −20° C. for 2 hours, and centrifuged. The supernatant was discarded and the precipitate was dried in air at room temperature for 10 min. The precipitated NTD was resuspended in 5 mL of pure HPLC-grade water. Finally, the resuspended sample was applied to pre-equilibrated Superdex 75 10/300 gel-filtration column with filter-sterilized HPLC-grade water. Peak fractions containing NTD were pooled, lyophilized and resuspended in HPLC-grade water to desired concentration. 5 L of cells typically yield 15 mg of NTD, at least 95% pure according to SDS-PAGE and MALDI-TOF analysis. Mutant NTD carrying His30Ala/His36Ala/His48Ala/His54Ala/His66Ala mutations was purified the same way as the wild-type NTD.
Peptide synthesis. Wild-type HP motif peptide (HPSALAQPSGLAHP) and mutant HP motif peptide (APSALAQPSGLAAP) were synthesized using solid-phase synthesis and purified using HPLC by the Biopolymers & Proteomics Core at the Koch Institute for Integrative Cancer Research.
Heme absorbance-shift assay. Hemin was prepared fresh before each experiment. Approximately 20 mg of hemin (Sigma) was placed in a fresh tube and resuspended with 1 mL of DMSO. The hemin solution was slowly diluted while mixing with 1 mL of 2× buffer C (25 mM HEPES-NaOH pH 7.8, 10 mM NaCl), and aggregated hemin was eliminated by passing the solution through a 0.2 μm filter unit. Hemin concentration was determined by diluting the filtered solution with 1× buffer C 1:100 and using the extinction coefficient of 58,400 cm−1M−1 at 385 nm. For each reaction, the 200 μL reaction mix containing 100 μM hemin, 25 mM HEPES-NaOH pH 7.8, 10 mM NaCl, and various concentrations of wild-type or mutant NTD protein, was placed in a transparent 96-well plate. Absorbance intensity was measured using Tecan Infinite M200 Pro microplate reader, between 330 and 550 nm using 5 nm steps. The absorbance intensity for dissolved hemin was subtracted from absorbance intensity from hemin incubated with various concentrations of protein.
Gel-filtration assay. Purified NTD (200 μM) was incubated with freshly prepared heme (150 μM) in a 1 mL reaction containing 5% DMSO, 25 mM HEPES-NaOH pH 7.8, and 10 mM NaCl. The solution was run over Superdex 75 (24 mL) gel-filtration column at 0.3 mL/min rate using AKTA-FPLC. Absorbance was monitored at 230, 380, and 415 nm. 2 mL injection volume was subtracted from the final elution volume. Solution containing dissolved hemin in the reaction buffer without the NTD protein aggregated on top of the Superdex 75 column, thus this control was avoided in our experiments.
Isothermal titration calorimetry (ITC). ITC was performed using Microcal VP-ITC (Malvern). Freshly prepared 25 μM hemin solution (described above) in 10% DMSO, 25 mM HEPES-NaOH pH 7.8, was placed in the sample cell using bubble-free technique. The reference cell was filled with buffer containing 10% DMSO, 25 mM HEPES-NaOH pH 7.8 without hemin. The titration syringe was filled with 110 μM NTD protein in the matching buffer. The experiment was run following the manufacturer's instructions using the following parameters: temperature was set to 25° C., 27 total injections (the first injection was 1 μL with subsequent injections of 10 μL over 20 sec), differential power was set to 10, delay was 60 sec, and syringe was rotating at 307 rpm.
Antibodies, cell lines and flow cytometry. Antibodies specific for MFSD7C (Catalog No. HPA037984) for Western blotting or immunofluorescence were purchased from Sigma. Antibodies specific for SERCA2b (Catalog No. ab2861) for immunofluorescence were purchased from Abcam. Antibodies specific for SERCA2b (Catalog No. 4388) for Western blotting were purchased from Cell Signaling Technology. Anti-Calnexin (Catalog No. ab13504) for ER localization was purchased from Abcam. Anti-Myc (Catalog No. 5605), anti-HA (Catalog No. 2367) and anti-FLAG (Catalog No. 2368) antibodies were purchased from Cell Signaling Technology. Human SERCA2b (Catalog No. 75188) plasmid was purchased from Addgene. Cell lines THP-1 (ATCC TIB-202), MH-S (ATCC CRL-2019), and 293FT were cultured following vendor instructions (37° C., 5% CO2). FPT labeled cells were analyzed on BD-LSRII, collecting 20,000 live cells per sample. The data were analyzed using FlowJo.
Mouse whole brain cellular fractionation analysis. Whole brain from C57BL/6 mice was isolated, resuspended in PBS supplemented with 10 mM EDTA, and passed through 40 μm Falcon cell strainer (VWR). The resuspension was centrifuged at 1,200 g and washed twice more with PBS/10 mM EDTA. The pellet was resuspended in 35 mL of cold 1× MS Buffer (210 mM mannitol, 70 mM sucrose, 5 mM Tris-HCl pH 7.5, 1 mM EDTA) supplemented with 1% fatty acid-free BSA (Sigma). Cells were lysed using Dounce homogenizer with 10-15 strokes of the pestle, and the lysate was transferred to a 50 mL centrifuge tube and centrifuged at 1,300 g for 5 min at 4° C. to precipitate nuclei and unbroken cells. The supernatant was transferred to a fresh 50 mL centrifuge tube and the nuclear precipitation step was repeated two more times. The supernatant was then centrifuged at 10,000 g for 15 min at 4° C. to precipitate mitochondria. The supernatant was saved for analysis (Sup), while the crude mitochondrial pellet was washed once more by resuspending in 35 mL of ice-cold 1× MS Buffer plus 1% BSA followed by centrifugation at 10,000 g for 15 min at 4° C. Crude mitochondrial pellet was resuspended in 5 mL of 1× MS buffer, and mitochondria were used immediately for Western blot analysis (Mito). Western blot analysis was performed using the following antibodies: anti-MFSD7C (Sigma, Catalog No. HPA037984), anti-VDAC (Cell Signaling Technologies, Catalog No. 4661), anti-COX4I1 (Cell Signaling Technologies, Catalog No. 4850), anti-GAPDH (Cell Signaling Technologies, Catalog No. 5174), anti-NPM1 (Novus Biologicals, Catalog No. NB110-61646SS), anti-Calreticulin (Cell Signaling Technologies, Catalog No. 12238), anti-SERCA2b (Cell Signaling Technologies, Catalog No. 3010), and anti-LC3 (Cell Signaling Technologies, Catalog No. 2775).
DNA plasmids for IP-MS, localization, co-IP, genome editing. To construct MFSD7C tagged with FLAG and Myc epitopes for immunoprecipitation-mass spectrometry (IP-MS), GFP-P2A fragment was amplified with the primers Bgl II-NHEI-GFP-F and BamHI-P2A-GFP-R. The fragment was digested using Bgl II/Bam HI and inserted to the Bam HI site of the pLKO.1 vector (Addgene Catalog No. 10878) to obtain pLKO.1-GFP-P2A-Puro vector. The MFSD7C-FLAG-Myc fragment was amplified from the murine MFSD7C plasmid (Origene Catalog No. MR208748) using the primers MFSD7C-SgfI-F and AC-Myc-DDK-MluI-KpnI-R. The fragment was digested with SgfI and then with KpnI. The fragment was cloned into the SgfI and KpnI sites of pLKO.1-GFP vector to yield pLKO.1-GFP-P2A-MFSD7C-FLAG-Myc (
To construct MFSD7C-GFP fusion for localization study, MFSD7C fragment was amplified from the murine MFSD7C plasmid (Origene Catalog No. MR208748) with primers MFSD7C-SgfI-F and AC-Myc-DDK-MluI-KpnI-R and inserted into SgfI and MluI sites of pCMV6-AC-GFP vector (Origene Catalog No. PS100010) so that GFP is fused to the C-terminus of MFSD7C (
To construct various vectors for co-immunoprecipitation, MFSD7C fragment was amplified from the murine MFSD7C plasmid (Origene Catalog No. MR208748) with the primers MFSD7C-SgfI-F and AC-Myc-DDK-MluI-KpnI-R and inserted in SgfI and MluI sites of pCMV6-AN-3HA (Origene Catalog No. PS100066) so that HA tag is introduced into N-terminus of MFSD7C. Murine Hmox1 (Catalog No. MR203944), Cyc1 (Catalog No. MR204721), Cox4i1 (Catalog No. MR218332), Ndufa4 (Catalog No. MR216909), ATP5h (Catalog No. MR201260), ATP5c1 (Catalog No. MR204152) genes were purchased from Origene and were tagged with FLAG at the C-terminus.
To construct vectors for MFSD7C knockout in cell lines, mCherry fragment was amplified using the primers Bam HI-P2A-mCherry-F and mCherry-WRPE-R. WRPE fragment was amplified with the primers mCherry-WRPE-F and PmeI-R. The mCherry-WRPE fragment was amplified with primers Bam HI-P2A-F and PmeI-R using the mixture of mCherry fragment and WRPE fragment as templates. The mCherry-WRPE fragment and Lenti-CRISPR-V2 (Addgene Catalog No. 52961) were digested with Bam HI and PmeI and ligated to generate Lenti-CRISPR-V2-mCherry (
To construct MFSD7C full length to complement 7CKO 4B8 cells, 3 MFSD7C fragments was amplified from the murine MFSD7C plasmid (Origene Catalog No. MR208748) by primer pairs MFSD7C-AsiSI-F/MFSD7C-KpnI-R, MFSD7C-KpnI-F/MFSD7C-XmaI-R, MFSD7C-XmaI-F/MFSD7C-MluI-R. The three fragments were Gibson assembled to pLKO.1-GFP-P2A-MFSD7C-Myc-DDK that was linearized by AsiSI and MluI. The correct constructs (pLKO.1-GFP-P2A-FL-MFSD7C-Myc-DDK) were validated by Sanger sequencing and used for
All of the final constructs were confirmed by sequencing. See Table 1 for a list of primers, and Table 2 for a list of plasmids used in this study.
Generation of lentiviral vectors and stable cell lines. The protocols for lentiviral production and transduction were as described (http://www.addgene.org/tools/protocols/plko/). Briefly, the plasmids of lentivector, psPAX2 (packaging, Addgene Catalog No. 12260), and pMD2.G (envelope, Addgene Catalog No. 12259) were transfected into 293T cells for lentiviral production. The lentivirus was tittered and used to transduce the target cells. Transduced cells were purified by flow cytometry using the encoded fluorescence proteins in the lentivectors or were selected by puromycin using the resistance gene encoded in the lentivector. Murine alveolar macrophage cell line MH-S was transduced with pLKO.1-GFP-P2A-Puro and pLKO.1-GFP-P2A-MFSD7C-FLAG-Myc. GFP positive cells were sorted and expanded. Cell lysates were then used for immunoprecipitation, followed with mass spectrometry.
THP-1 cells were transduced with lentiviruses expressing mCherry, Cas9, and MFSD7C guide RNA-1 or -2 (
Immunoprecipitation and LC-MS/MS. Murine alveolar macrophage cell line MH-S, which expresses MFSD7C (
Peptides were loaded on a pre-column and separated by reverse phase HPLC (Thermo Easy nLC1000) over a 140-minute gradient before nanoelectrospray using a QExactive mass spectrometer (Thermo). The mass spectrometer was operated in a data-dependent mode. The parameters for the full scan MS were: resolution of 70,000 across 350-2000 m/z, AGC 3e6, and maximum IT 50 ms. The full MS scan was followed by MS/MS for the top 10 precursor ions in each cycle with a NCE of 28 and dynamic exclusion of 30 s. Raw mass spectral data files (.raw) were searched using Proteome Discoverer (Thermo) and Mascot version 2.4.1 (Matrix Science). Mascot search parameters were: 10 ppm mass tolerance for precursor ions; 0.8 Da for fragment ion mass tolerance; 2 missed cleavages of trypsin; fixed modification was carbamidomethylation of cysteine; variable modification was methionine oxidation. Only peptides with a Mascot score greater than or equal to 25 and an isolation interference less than or equal to 30 were included in the data analysis. Potential interacting proteins are identified in the experimental sample after removal of proteins in the control sample and common contaminating proteins.
The mass spectrometry proteomics data have been deposited to the ProteomeXchange Consortium via the PRIDE partner repository with the dataset identifier PXD021016 (http://www.ebi.ac.uk/pride/archive/projects/PXD021016).
Co-transfection and immunoprecipitation. For co-IP, HA-tagged MFSD7C was co-transfected with FLAG-tagged HMOX1 (Origene Catalog No. MR203944), CYC1, COX4I1, NDUFA4, ATP5h, ATP5c1 into 293FT cells using TransIT®-LT1 Transfection Reagent (Mirus). Thirty-six hours after transfection, the cells were lysed using cold Lysis Buffer containing 20 mM Tris-HCl (pH 7.4), 150 mM NaCl, 0.1% NP-40, 10% glycerol, proteinase inhibitor (Sigma Catalog No. 4693132001), and phosphatase inhibitors (Sigma Catalog No. 4906845001). The clear supernatants from the lysate were incubated with M2-magnetic beads conjugated with anti-FLAG antibody (Sigma Catalog No. M8823) for 2 hours at 4° C. Then the beads were washed twice and eluted by the 3× FLAG peptides (Sigma Catalog No. F4799).
To determine the effect of heme on MFSD7C interactions with ETC components, HMOX1 or SERCA2b, 293FT cells were transiently transfected with HA-tagged murine MFSD7C and FLAG-tagged murine CYC1, NDUFA4, COX4i1, ATP5h, ATP5c1, HMOX1 or SERCA2b. 35 hrs later, co-transfected cells were incubated with DMSO (vehicle) or 10 μM or 40 μM of heme for one hour before lysis. Cell lysates were precipitated with anti-HA antibody, eluted with HA peptide, further precipitated with anti-FLAG antibody, eluted with FLAG peptide, and then subjected to Western blotting with anti-HA and anti-FLAG antibodies. Cells were treated with proteasome inhibitor MG132 for co-IP between MFSD7C and SERCA2b.
Endogenous protein extraction. THP-1 cells were lysed in RIPA buffer (25 mM Tris·HCl pH 7.4, 150 mM NaCl, 1% NP-40, 1% sodium deoxycholate, 0.1% SDS) with proteinase and phosphatase inhibitors (Sigma Catalog No. 4693132001 and 4906845001). The clear supernatants were used for Western blotting.
Imaging analysis of MFSD7C localization. For MFSD7C localization, 293FT cells over-expressing GFP- or mCherry-tagged MFSD7C were grown on coverslips in tissue culture and stained for mitochondria using 100 nM MitoTracker® Deep Red FM (Thermo-Fisher Catalog No. M22426) for 20 min in serum-free medium, per manufacturer's protocol. Cells were fixed using 3.5% paraformaldehyde (in 1× PBS, pH 6.7) for 10 minutes and permeabilized with 0.5% Triton-X in 1× TBS-BSA (10 mM Tris HCl pH 7.5, 150 mM NaCl, 1% BSA, 0.1% NaN3) for another 10 minutes. Anti-human HLA-A, B, C (Biolegend W6/32) was added at a 1:1000 dilution in 1× TBS-BSA+0.1% Triton-X for 1 hour at room temperature. Anti-mouse Alexa 647 (Life Technologies Catalog No. A31571) at a 1:2000 dilution was added to DAPI in 1× TBS-BSA and incubated with the cells for 1 hour.
Coverslips were attached to glass slides using ProLong® Diamond Antifade Mountant with DAPI (Thermo-Fisher, Catalog No. P36962) and imaged using a Nikon A1R Ultra-Fast Spectral Scanning Confocal Microscope using Elements software. Images were taken in z-stacks of 0.2 μm and flattened using the max projection function in ImageJ.
Measurements of OCR, ECAR, and MMP. Oxygen consumption rate (OCR) and extracellular acidification rate (ECAR) were measured using XF96e Seahorse Extracellular Flux Analyzer per manufacturer's protocol. To increase adherence of suspension cells, Seahorse plates were coated with Corning® Cell TAK (Catalog No. 354240). THP-1 and 7CKO cells were then attached to the plate according to the manufacturer's instructions. Cells were incubated in complete RPMI media with or without 40 μM heme. Changes in oxygen consumption were measured following treatment with oligomycin (5 μM), FCCP (2 μM), and rotenone (1 μM) plus antimycin A (1 μM). For BMDM, 5×105 cells/well were plated in 100 μL of BMDM media, 24 hours before the start of the assay. For OCR measurements, BMDM media was replaced with 180 μL of Seahorse XF Base Medium supplemented with 10 mM D-glucose, 1 mM sodium pyruvate, and 1 mM L-glutamine. For ECAR measurements, BMDM media was replaced with 180 μL of Seahorse XF RPMI Medium pH 7.4 supplemented with 2 mM L-glutamine. The Glycolysis Stress Test was performed using D-glucose, rotenone/antimycin A, and 2-deoxy-D-glucose at 10 mM, 0.5 μM, and 50 mM final concentration, respectively.
Mitochondrial membrane potential was measured using Abcam kit (Catalog No. ab113852). Briefly, BMDM, THP-1 and 7CKO cells were not treated or treated with 40 heme for 1 hour. The cells were incubated with mitochondrial membrane potential indicator, 200 nM TMRE (tetramethylrhodamine, ethyl ester) for 20 minutes. The mean fluorescence intensity of TMRE were determined by flow cytometry.
Measurement of cellular energy charge (ATP/ADP ratio). ATP/ADP ratio was measured using ADP Assay Kit (Sigma Catalog No. MAK133-1KT) following manufacturer's protocol. For THP-1 cells, 24 hours before the experiment, cells were resuspended in fresh complete RPMI media. For heme treatment, 1 mL of treated cell suspension was incubated for 1 hour at 37° C. cell culture incubator, then centrifuged and resuspended in 1 mL of fresh warm complete RPMI media in order to wash off excess heme, which interferes with the assays. 10 of cell suspension per well (approximately 10,000 cells total) was placed in a white 96-well plate, lysed with 90 μL of ATP Buffer, and incubated with gentle shaking at room temperature for 10 min. Relative ATP amount was directly measured using luminescence. Then, 5 μL of ADP Enzyme mix was added to each well and the plate was incubated with light shaking for 3 minutes. Relative amount of ADP+ATP was measured using luminescence. ADP amount was calculated by subtracting the ATP signal from ADP+ATP signal. To get ATP/ADP ratio, ATP signal was divided by the calculated ADP signal. For BMDMs, the assay was performed following the same protocol but using 20,000 cells per well.
Alternatively, ATP, ADP, and AMP levels were measured using targeted metabolomic analysis at the Whitehead Institute Metabolite Profiling Core Facility. Briefly, 100,000 cells (parental THP-1 cells and 7CKO clone B11, 3 independent experiments each) were centrifuged, and resuspended in 500 μL of cold 0.9% NaCl. Metabolites were extracted with the addition of 600 μL LC/MS-grade cold methanol containing internal standards, and the mixture was vortexed for 2 min. Then 300 μL LC/MS grade water was added to each tube, followed by 400 μL cold chloroform. The mixture was vortexed again in the cold room and then spun at 16,000 g in a microcentrifuge. The top layer containing polar metabolites was transferred to a clean tube and the sample was dried using speedvac. Ultra-pressure liquid chromatography was performed using pHILIC column on Dionex UltiMate 3000 and mass-spectrometry was performed using Thermo Scientific QExactive Orbitrap instruments.
Synthesis of fluorescent polymeric thermometer. 4-N,N-Dimethylaminosulfonyl-7-fluoro-2,1,3-benz-oxadiazole (DBD-F) was purchased from TCI Chemicals. N-n-propylacrylamide (NNPAM) and N-ethylacrylamide (NEAM) were purchased from AstaTech. N,N′-dimethylethylenediamine, acryloyl chloride, triethylamine (TEA), (3-acrylamidopropyl) trimethylammonium chloride (APTMA Cl), azobisisobutyronitrile (AIBN) and other solvents were purchased from MilliporeSigma. All commercial acrylamide monomers were passed through a basic alumina column to remove inhibitors before polymerization. Other reagents were used as purchased.
The synthesis was slightly modified from the protocol in the literature. Briefly, 100 mg DBD-F is dissolved in 5 mL anhydrous acetonitrile, then added dropwise into a stirring vial containing 1.3 mL N, N′-dimethylethylenediamine. The mixture was allowed to react for 15 minutes at room temperature. The reaction mixture was condensed with rotatory evaporation and purified with silica gel liquid chromatography using eluent dichloromethane:methanol from 10:1 to 5:1, fractions were collected and monitored with thin layer chromatography. DBD-NMe(CH2)2NHMe was obtained as an orange liquid.
130 mg DBD-NMe(CH2)2NHMe was dissolved in 5 mL of anhydrous acetonitrile mixed with 58 μL of TEA and cooled on ice. 44 μL acryloyl chloride was dissolved in 8 mL of anhydrous acetonitrile, cooled on ice and then added dropwise into the reaction mixture. The reaction was allowed to proceed for 1.5 hours at room temperature then condensed with rotatory evaporation and purified with silica gel liquid chromatography using eluent ethylacetate:hexane 3:1. Fractions were collected and monitored with thin layer chromatography. DBD-AA was obtained as an orange powder (
The polymer synthesis was modified from the protocols described in the literature. Briefly, 4.1 mg AIBN, 20 mg DBD-AA, 41 mg APTMA Cl, 565 mg NNPAM (for fluorescent polymeric thermometer) or 495 mg NEAM (for control polymer that is not temperature sensitive), 5 mL DMF and a stir bar were added into a clean schlenk flask. The flask was sealed and purged with nitrogen for 30 mins at room temperature to remove dissolved oxygen. The flask was then immersed in 60° C. oil bath to initiate the polymerization. After 12 hours of reaction, the reaction mixture was precipitated in cold ethyl ether (0° C.) and redissolved in DMF for three times, then dried in vacuo overnight for use (
Measurements of cellular thermogenesis. Three methods were used to measure cell thermogenesis. In the first approach, we used thermocouple. Three million THP-1 and 7CKO cells were re-suspended in 100 μl media (RT, room temperature) and transferred to PCR tubes tightly fitted in a thermally insulating enclosure. Then the temperature change rate of media (ΔTm/Δt) was monitored real-time by type T-Type Thermocouples (Omega, Catalog No. 5SC-TT-T-3036) immersed in the liquid media. An analog to digital converter (National Instruments 24-bit Thermocouple ADC) was used to obtain and store the thermocouple data via a custom Labview interface (sampling rate: 500 ms). Every measurement was compared to the free liquid media.
In the second approach, we used fluorescent polymeric thermometer (FPT), which we synthesized in-house (see above). Parental and knockout THP-1 cells were mixed together, washed and incubated with FPT in 5% w/v glucose solution for 6 hrs. The cells were washed with PBS twice and reseeded in dishes with glass bottom that was coated with poly-lysine. The cells were imaged under Confocal Laser-Scanning Microscopy at 37° C. Alternatively, THP-1, MCF7, 293T, 7CKO, SERCA2b−/− cells were incubated with FPT and control polymer overnight and followed with vehicle or hematin treatment for 1 hour. Then the fluorescence intensities were determined by a flow cytometer.
In the third approach, we used commercial cellular fluorescent thermoprobe dye (Funakoshi Catalog Number: FDV-0005). Briefly, one day before the assay, 2×105 BMDMs were plated in a 48-well non tissue-culture treated polystyrene plate in 200 μL of BMDM media. BMDM media were aspirated and cells were washed once with Loading Solution (5% (w/v) aqueous glucose solution supplemented with 10 mM EDTA). Next, 200 μL of Loading Solution supplemented with 50 ng/μL Cellular Thermoprobe Dye was added to the well and loading of the dye was performed in a 33° C., 5% CO2 cell culture incubator for 7.5 minutes, which simultaneously lifts BMDMs from the well. In the next 2.5 minutes, the plate was removed from the incubator, cells were resuspended by pipetting and moved to a PCR tube and combined with 22 μL of 10× PBS/DAPI buffer. The mixture in the PCR tube was then placed in a thermocycler with a preset temperature, incubated for 5 min, and immediately analyzed using flow cytometry (BD LSR II). Cells are gated based on size (singlets) and DAPI (live cells). 15,000 FITC-positive cells were collected for the analysis. Special care was taken with regards to timing because the loading of the Cellular Thermoprobe Dye is dependent on the amount of time the cells are incubated with the dye. Different filters were used to measure loading and temperature sensitivity due to properties of Cellular Thermoprobe Dye. For loading measurements, excitation at 488 nm with 515/20 emission filter was used, while thermosensitive analysis was performed using excitation at 488 nm with 530/30 emission filter.
Generation of Mfsd7c mutant mice. C57BL/6N ES cell clone with foxed exon 2 of Mfsd7c was purchased from EuMMCR (European Mouse Mutant Cell Repository, ES cell Clone ID: HEPD0572_8_F01). The ES cells were transfected with plasmids encoding FLP to remove neomycin resistance cassette. The G418 sensitive ES cells with properly floxed exon 2 of Mfsd7c were confirmed using PCR and Sanger Sequencing. The ES cells were injected into blastocysts and then transferred into pseudopregnant mice at the Koch Institute Swanson Biotechnology Center. Germline mutant mice were identified based on the coat color and Mfsd7cwt/fl heterozygous mice were interbred to generate homozygous Mfsd7cfl/fl mice. Mfsd7cfl/fl mice were bred with LysM-Cre mice (the Jackson Laboratory, Stock No: 004781) to generate myeloid-specific Mfsd7c knockout. Mice were maintained in the animal facility at the Massachusetts Institute of Technology (MIT). All animal studies and procedures were carried out following federal, state, and local guidelines under an IACUC-approved animal protocol by Committee of Animal Care at MIT.
Mouse genomic DNA extraction, genotyping, and qPCR. A small piece of mouse tail was cut using scissors, placed in 500 μL of Genomic DNA Extraction Buffer (100 mM Tris-HCl pH 8.0, 200 mM NaCl, 5 mM EDTA, 0.2% SDS, 0.5 mg/mL Proteinase K) and digested overnight at 55° C. Digested tissue was centrifuged at 13,000 g for 5 min, and the cleared supernatant was transferred to a fresh 1.5 mL tube. Genomic DNA was precipitated from the supernatant with isopropanol (50% v/v), and centrifuged at 13,000 g for 2 min. Supernatant was discarded, and the precipitate was washed with 1 mL of 70% ethanol. Ethanol was discarded and the precipitate was left to dry at room temperature for 5 min. DNA was resuspended in 200 μL of nuclease-free ddH2O. Genomic DNA from bone marrow-derived macrophages was isolated from 5×105 cells using the same protocol. Primer set #1 and #2 were used to genotype wild-type, floxed and deleted alleles, and LysM-Cre primers were used to detect the presence of Cre recombinase (see Table 1 for primer sequences).
For qPCR analysis, 106 bone marrow-derived macrophages were rinsed with PBS, lysed in RLT buffer (Qiagen), and flash-frozen in liquid nitrogen. After thawing on ice and passing through a 27 G needle multiple times, RNA was isolated using Qiagen's RNEasy Mini kit. cDNA was synthesized using Superscript IV (Invitrogen) and random hexamers, followed by RNA removal using E. coli RNase H for 20 minutes at 37° C. cDNA was diluted tenfold and qPCR was performed in triplicate using 4 μL diluted cDNA, 0.5 μL 5 μM forward primer, 0.5 μL 5 μM reverse primer, and 5 μL 2× SYBR Green Master Mix (Roche) per well in a 96-well plate (see Table 2 for primer sequences). A Roche Lightcycler 480 instrument was used measuring amplification for 45 cycles using Roche's SYBR Green protocol, after which melting temperatures and crossing points were assessed and quantified.
Differentiation of bone marrow-derived macrophage (BMDM). Mfsd7cfl/fl and Mfsd7c−/− (Mfsd7cfl/fl LysMCre+/+) C57BL/6J mice were euthanized using CO2 asphyxiation. Femoral bones were removed and cleaned and the bone marrow was flushed out using 5 mL of cold DMEM media. Bone marrow cells were collected by centrifugation (1,200 g for 5 min at 4° C.) and resuspended in 4 mL of ACK lysis buffer. After incubation at room temperature for 5 min, ACK buffer was neutralized by the addition of 11 mL of cold DMEM media and cell suspension was centrifuged at 1,200 g for 5 min at 4° C. Cells were resuspended in DMEM media containing 10% FBS, 2 mM L-glutamine, 2 mM pyruvate, non-essential amino acids (100 μM each), 0.55 mM 2-mercaptoethanol, penicillin/streptomycin), passed through a 40 μm Falcon cell strainer (VWR) to remove large aggregates, and counted. Bone marrow cells were seeded in 10 cm non tissue-culture treated plates at 10 million cells per plate in 10 mL of BMDM media. Two days later, additional 10 mL of BMDM media was added. On day 4 and day 6, old media was removed and 10 mL of fresh media was added. On day 7, fully differentiated BMDM were lifted in phosphate-buffered saline supplemented with 10 mM EDTA for 5 min at 37° C., centrifuged and resuspended in BMDM media to a proper density for further experimentation.
Sequence and structural analyses predict that MFSD7C belongs to the 12-transmembrane solute carrier family. The NTD of human and mouse MFSD7C contains five regularly spaced histidine-proline (HP) repeats, a feature conserved in many mammalian species (
We used immunoprecipitation (IP) and mass spectrometry (MS) to identify proteins that interact with MFSD7C. Because an anti-MFSD7C monoclonal antibody is not available, we used MFSD7C tagged with both Myc and FLAG epitopes in a MFSD7C-expressing murine alveolar macrophage cell line MH-S (
To validate the IP-MS results, we tested interactions between MFSD7C and heme oxygenase-1 (HMOX1) and all five ETC proteins: CYC1 (complex III), NDUFA4 and COX4I1 (complex IV), ATP5h and ATP5c1 (complex V/ATP synthase) by co-IP. Plasmids encoding HA-tagged MFSD7C and FLAG-tagged candidate proteins were co-transfected into HEK 293T cells and cell lysates were precipitated with anti-FLAG and anti-HA antibodies sequentially, followed by Western blotting with anti-HA or anti-FLAG antibodies. MFSD7C co-precipitated with all six proteins tested (
To determine MFSD7C subcellular localization, we performed subcellular fractionation followed by Western blotting on whole mouse brain where MFSD7C is strongly expressed34. MFSD7C was only detectable in the mitochondrial fraction (10,000 g precipitate), along with mitochondrial markers VDAC and COX4I1 (
Together, these data suggest that MFSD7C primarily resides in mitochondria where it interacts with components of the ETC complexes III, IV and V.
To investigate the function of MFSD7C, we generated four independent Mfsd7c knockout clones (A11, B11, 3D12 and 4B8, collectively referred to as 7CKO cells) using CRISPR-Cas9 genome editing in THP-1 cells, which had readily detectable levels of MFSD7C but not UCP1 (
We measured the effect of Mfsd7c knockout and heme on thermogenesis using a temperature-sensitive dye: fluorescent polymeric thermometer (FPT, see Methods and
To validate the observed effects in different cell types, we knocked out Mfsd7c in human breast cancer MCF7 cells and human embryonic kidney 293T cells using CRISPR-Cas9 genome editing (
To test whether loss of Mfsd7c uncouples mitochondrial respiration in primary cells, we created a C57BL/6 mouse strain with loxP sites flanking exon 2 of Mfsd7c (Mfsd7cfl/fl). Mfsd7clf/fl mice were crossed with LysMcre mice to deplete Mfsd7c (Mfsd7c−/−) specifically in myeloid cells (
The fact that heme treatment phenocopies the effect of Mfsd7c knockout suggests that heme may work by disrupting MFSD7C interactions with ETC components. To test this hypothesis, we performed co-IP between MFSD7C and the ETC components with or without treating the cells with 10 μM or 40 μM heme for one hour before cell lysis. As expected, CYC1, NDUFA4, COX4i1, ATP5h, and ATP5c1 co-precipitated with MFSD7C without heme treatment (
To delineate the relationship between the heme-binding by the NTD in vitro and the effect of heme on OCR and thermogenesis in vivo, we complemented 7CKO clone 4B8 with either the full length MFSD7C (MFSD7CFL) or MFSD7C lacking the first 80 amino acid residues of the NTD (MFSD7CΔN) to generate 4B8FL and 4B8ΔN cells, respectively (
How does Mfsd7c knockout or heme treatment induce thermogenesis? We noticed that SERCA2b (a.k.a. ATP2a2) was identified as a MFSD7C-interacting protein by IP-MS (Table 1). We validated the interaction by co-IP in 293T cells. In the absence of proteasome inhibitor MG132, a low level of SERCA2b was detected but none was co-precipitated with MFSD7C (
Stabilization of SERCA2b by proteasome inhibitor MG132 suggests that MFSD7C may promote SERCA2b degradation through ubiquitination and subsequent proteasomal degradation. To test this hypothesis, 293T cells were transfected with FLAG-tagged SERCA2b and treated with MG132 for either 6 or 12 hours, lysed, immunoprecipitated with anti-FLAG, and Western blotted with anti-MFSD7C, anti-SERCA2b and anti-ubiquitin antibodies. With longer MG132 treatment, more full-length and ubiquitinated SERCA2b was precipitated (
To investigate the role of SERCA2b in MFSD7C/heme-regulated thermogenesis, we tested if heme-stimulated thermogenesis is inhibited by thapsigargin, a known SERCA2b inhibitor. Indeed, heme-stimulated thermogenesis in THP-1 cells was mostly inhibited by thapsigargin (
All publications and patents mentioned herein are hereby incorporated by reference in their entirety as if each individual publication or patent was specifically and individually indicated to be incorporated by reference. In case of conflict, the present application, including any definitions herein, will control.
While specific embodiments of the subject invention have been discussed, the above specification is illustrative and not restrictive. Many variations of the invention will become apparent to those skilled in the art upon review of this specification and the claims below. The full scope of the invention should be determined by reference to the claims, along with their full scope of equivalents, and the specification, along with such variations.
This application claims the benefit of priority to U.S. Provisional Patent Application Ser. No. 63/073,155, filed Sep. 1, 2020; the contents of which are hereby incorporated herein by reference in their entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/US2021/048370 | 8/31/2021 | WO |
Number | Date | Country | |
---|---|---|---|
63073155 | Sep 2020 | US |