Methods for increasing and/or promoting wound healing, wound re-epithelialization and dermal regeneration of epithelial tissues and cutaneous wounds by administration to a subject of an extracellular matrix scaffold or Scaffold for Dermal Regeneration (SDR) populated with beta adrenergic receptor antagonist pre-conditioned mesenchymal stem cells (MSCs) are provided. Compositions and kits comprising an extracellular matrix scaffold or Scaffold for Dermal Regeneration (SDR) populated with beta adrenergic receptor antagonist pre-conditioned mesenchymal stem cells (MSCs) are also provided.
Stress plays an important role in wound healing and some of the most potent mediators of stress are the catecholamines, such as epinephrine and norepinephrine. It has been shown that epinephrine can activate beta adrenergic receptors on human keratinocytes causing them to release inflammatory mediators such as IL-6. An estimated 40-60% of diabetes (DB) patients are at risk for the development of DB foot complications, and DB foot wounds (DFW) account for over 20% of all hospitalizations of DB patients. These wounds are extremely unmanageable resulting in an estimated 82,000 non-traumatic lower limb amputations each year, in other words, one amputation every 30 seconds in DB patients.
Current topical methods for treating DFW includes debridement to remove necrotic and infected tissues, dressings to provide a moist wound environment, bandages, and topical applications of antimicrobial or biologic agents, offloading, physical therapies, and educational strategies. However, these different treatment modalities often fail to achieve complete wound closure since they do not address the main culprit, i.e., persistent inflammation. For example excessive use of antibiotics may address bacterial numbers and to some extent inflammation but can lead to the development of resistant strains.
In one aspect, provided are extracellular matrix scaffolds. In some embodiments, the extracellular matrix scaffolds comprise mesenchymal stem cells (MSCs) which have been contacted and/or pre-conditioned with and/or exposed to a beta adrenergic receptor antagonist. In some embodiments, the MSCs have been cultured in medium comprising a beta adrenergic receptor antagonist. In varying embodiments, the MSCs have been cultured in medium comprising a beta adrenergic receptor antagonist at a concentration in the range of about 0.2 μM to about 50 μM, e.g., about 0.4 μM to about 40 μM, e.g., about 0.3 μM to about 30 μM, e.g., about 0.2 μM to about 20 μM, e.g., about 1.0 μM to about 10 μM. In varying embodiments, the MSCs have been cultured at least 24 hours, e.g., at least about 48 hours in medium comprising a beta adrenergic receptor antagonist. In varying embodiments, the MSCs have been cultured under hypoxic conditions. In some embodiments, the antagonist has a Kd for a beta-3 adrenergic receptor that is about 100 or more times greater than a Kd of the antagonist for a non-beta-3 (e.g., for a β1 and/or β2) adrenergic receptor. In some embodiments, the beta adrenergic receptor antagonist is non-selective antagonist for β1 and β2 adrenergic receptors. In some embodiments, the beta adrenergic receptor antagonist is selected from carteolol, carvedilol, labetalol, nadolol, penbutolol, pindolol, propranolol, sotalol, timolol, and mixtures, analogs and salts thereof. In some embodiments, the beta adrenergic receptor antagonist is selective antagonist for β1 adrenergic receptors. In some embodiments, the beta adrenergic receptor antagonist is selected from acebutolol, atenolol, betaxolol, bisoprolol, celiprolol, esmolol, metoprolol, nebivolol, and mixtures, analogs and salts thereof. In some embodiments, the beta adrenergic receptor antagonist is selective antagonist for β2 adrenergic receptor. In some embodiments, the selective antagonist for β2 adrenergic receptor is selected from butoxamine and ICI-118,551. In some embodiments, the beta adrenergic receptor antagonist is selected from the group consisting of timolol, labetalol, dilevelol, propanolol, carvedilol, nadolol, carteolol, penbutolol, sotalol, ICI-118,551, butoxamine, and mixtures, analogs and salts thereof. In some embodiments, the beta adrenergic receptor antagonist is substantially free of activity as a beta-3 adrenergic receptor agonist. In some embodiments, the beta adrenergic receptor antagonist is attached to, e.g., via covalent bonding or crosslinking, to the scaffold. In varying embodiments, the MSCs are adipose-derived MSCs (Ad-MSCs). In varying embodiments, the MSCs are bone-marrow-derived MSCs (BM-MSCs).
In a further aspect, provided are kits comprising an extracellular matrix scaffold as described above and herein.
In another aspect, provided are methods of promoting, facilitating, and/or increasing healing, closure, re-epithelization and/or dermal regeneration of an epithelial and/or cutaneous wound in a subject in need thereof, comprising placing, implanting, suturing or embedding onto or into the wound an extracellular matrix scaffold as described above and herein. In varying embodiments, the subject has diabetes. In some embodiments, the subject is a human. In some embodiments, the wound comprises an incision, a laceration, an abrasion, or an ulcer. In some embodiments, the wound is a chronic wound. In some embodiments, the wound comprises a venous stasis ulcer, a diabetic foot ulcer, a neuropathic ulcer, or a decubitus ulcer. In some embodiments, the wound comprises a wound resulting from surgical wound dehiscence. In some embodiments, the wound comprises a burn. In some embodiments, the epithelial wound comprises skin. In varying embodiments, the MSCs are syngeneic to the subject. In varying embodiments, the MSCs are autologous to the subject. In varying embodiments, the MSCs are allogeneic to the subject. In varying embodiments, the MSCs are xenogeneic to the subject. In varying embodiments, the wound is sterile. In varying embodiments, the wound is not sterile. In varying embodiments, the beta adrenergic receptor antagonist is applied multiple times to the extracellular matrix scaffold that has been sutured, embedded or implanted into the wound.
Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art. The following definitions supplement those in the art and are directed to the current application and are not to be imputed to any related or unrelated case, e.g., to any commonly owned patent or application. Although any methods and materials similar or equivalent to those described herein can be used in the practice for testing, the preferred materials and methods are described herein. Accordingly, the terminology used herein is for the purpose of describing particular embodiments only, and is not intended to be limiting.
As used in this specification and the appended claims, the singular forms “a,” “an” and “the” include plural referents unless the context clearly dictates otherwise. Thus, for example, reference to “a receptor” includes a plurality of receptors; reference to “a cell” includes mixtures of cells, and the like.
The term “about” as used herein indicates the value of a given quantity varies by +/−10% of the value, or optionally +/−5% of the value, or in some embodiments, by +/−1% of the value so described.
The term “topical” refers to administration or delivery of a compound (e.g., a beta adrenergic receptor antagonist) by application of the compound to a surface of a body part. For example, a compound can be topically administered by applying it to skin, to the surface of a wound within the skin, a mucus membrane, or wound within the mucous membrane, or another body surface, or wound within. Topical administration can result, e.g., in either local or systemic delivery of a compound.
An “antagonist” is a compound (e.g., a drug) that can bind to a receptor and prevent an agonist from binding to and activating that receptor. Typically, binding of an antagonist to a receptor forms a complex which does not give rise to any response, as if the receptor were unoccupied. Alternatively, the antagonist can be a partial agonist.
It is worth noting that certain compounds can be classified as both an agonist and an antagonist. For example, a “mixed agonist-antagonist” (also called a “partial agonist”) is a compound which possesses affinity for a receptor, but which, unlike a full agonist, will elicit only a small degree of the response characteristic of that receptor, even if a high proportion of receptors are occupied by the compound. Such occupancy of the receptors by the partial agonist can prevent binding of a full agonist (e.g., an endogenous agonist) to the receptor.
The term “co-administering” or “concurrent administration”, when used, for example with respect to the compounds (e.g., one or more antagonists of a beta-adrenergic receptor) and/or analogs thereof and another active agent (e.g., an anesthetic, an antibiotic), refers to administration of the compound and/or analogs and the active agent such that both are in the blood at the same time. Co-administration can be concurrent or sequential.
The term “effective amount” or “pharmaceutically effective amount” refer to the amount and/or dosage, and/or dosage regimen of one or more compounds necessary to bring about the desired result e.g., an amount sufficient to promote, increase and/or facilitate wound healing, closure, re-epithelialization and/or dermal regeneration of an epithelial or cutaneous wound in a subject.
The phrase “cause to be administered” refers to the actions taken by a medical professional (e.g., a physician), or a person controlling medical care of a subject, that control and/or permit the administration of the agent(s)/compound(s) at issue to the subject. Causing to be administered can involve diagnosis and/or determination of an appropriate therapeutic or prophylactic regimen, and/or prescribing particular agent(s)/compounds for a subject. Such prescribing can include, for example, drafting a prescription form, annotating a medical record, and the like.
As used herein, the terms “treating” and “treatment” refer to delaying the onset of, retarding or reversing the progress of, reducing the severity of, or alleviating or preventing either the disease or condition to which the term applies (e.g., epithelial and/or cutaneous wound healing, closure, re-epithelialization and/or dermal regeneration), or one or more symptoms of such disease or condition.
As used herein, the phrase “consisting essentially of” refers to the genera or species of active pharmaceutical agents recited in a method or composition, and further can include other agents that, on their own do not have substantial activity for the recited indication or purpose.
The terms “subject,” “individual,” and “patient” interchangeably refer to any mammal, including humans and non-human mammals, e.g., primates, domesticated mammals (e.g., canines and felines), agricultural mammals (e.g., bovines, ovines, equines, porcines) and laboratory mammals (e.g., rats, mice, rabbits, guinea pigs, hamsters), as described herein.
The terms “increasing,” “promoting,” “enhancing” with respect to wound healing refers to increasing the epithelialization, closure and/or dermal regeneration of a wound in a subject by a measurable amount using any method known in the art. The wound healing is increased, promoted or enhanced if the re-epithelialization, closure and/or dermal regeneration of the wound is at least about 10%, 20%, 30%, 50%, 80%, or 100% increased in comparison to the re-epithelialization, closure and/or dermal regeneration of the wound prior to administration of beta adrenergic receptor antagonist conditioned mesenchymal stem cells (MSCs), e.g., over a predetermined time period. In some embodiments, the re-epithelialization, closure and/or dermal regeneration of the wound is increased, promoted or enhanced by at least about 1-fold, 2-fold, 3-fold, 4-fold, or more in comparison to the re-epithelialization, closure and/or dermal regeneration of the wound prior to administration of the beta adrenergic receptor antagonist conditioned MSCs.
The terms “reducing,” “decreasing” with respect to wound size refers to reducing or decreasing the open wound surface area or the wound volume in a subject by a measurable amount using any method known in the art. The wound surface area or volume in a subject is reduced or decreased if the measurable parameter of the wound is at least about 10%, 20%, 30%, 50%, 80%, or 100% reduced or decreased in comparison to the measurable parameter of the one or more symptoms prior to administration of the beta adrenergic receptor antagonist conditioned MSCs. In some embodiments, the measurable parameter of the wound surface area or volume is reduced or decreased by at least about 1-fold, 2-fold, 3-fold, 4-fold, or more in comparison to the measurable parameter of the one or more symptoms prior to administration of the beta adrenergic receptor antagonist conditioned MSCs.
The term “mesenchymal stem cells” refers to stem cells defined by their capacity to differentiate into bone, cartilage, and adipose tissue. With respect to cell surface markers, MSCs generally express CD44 and CD90, and should not express CD34, CD45, CD80, CD86 or MHC-II.
Provided are methods for the use of beta adrenergic receptor antagonist pre-conditioned human mesenchymal stem cells (MSC) embedded in an extracellular matrix Scaffold for Dermal Regeneration (SDR) for the treatment of epithelial and/or cutaneous wounds, e.g., diabetic wounds, venous and decubitus ulcers.
The present methods, compositions and kits are based, in part, on the surprising discovery that the combined use of a beta adrenergic receptor antagonist, MSCs, and SDR as an effective therapeutic device for the treatment of epithelial and/or cutaneous wounds, e.g., diabetic wounds. Herein we demonstrate that stress-induced inflammatory responses in full thickness cutaneous wounds of diabetic mice can be reduced by the addition of beta adrenergic receptor antagonists. Current topical therapies focus on the use of medications such as antibiotics, hyperbaric oxygen, all-trans retinoic acid, antimicrobials, among other treatments, but no treatments have utilized beta adrenergic receptor antagonists in conjunction with MSCs and SDR. Thus, we report the novel topical use of beta adrenergic receptor antagonist-conditioned MSC embedded in SDR for the treatment of epithelial and/or cutaneous wounds, e.g., diabetic wounds.
We have shown that inflammation plays a pivotal role in impaired wound healing in diabetic mice. Furthermore, we have shown that epinephrine can increase the release of inflammatory mediators and that use of a beta adrenergic receptor antagonist, such as timolol or ICI-118551, leads to suppression of the release of IL-6 by human keratinocytes. MSC are useful cellular therapy candidates for wound healing and commercially available extracellular matrix scaffolds for dermal regeneration (e.g., Integra) are currently in use for the treatment of burn and other wounds. Herein we demonstrate that beta antagonist-preconditioned MSC in SDR is useful for the suppression of the inflammatory response and improve healing. Further, a topical solution of a beta antagonist (timolol) can be applied to the MSC+SDR implanted, sutured or embedded in the diabetic wound (e.g., every other day or as appropriate) to continue the conditioning of the MSC with the beta adrenergic receptor antagonist.
Beta adrenergic receptor antagonists are widely used in medical practice both as systemic agents for cardiovascular disease and as topical agents for the eye. Illustrative beta adrenergic receptor antagonists of use include without limitation timolol and ICI-118551. Timolol is already in use as an FDA approved drug for use for glaucoma. Integra (SDR) is an FDA approved wound care device comprised of a porous matrix of cross-linked bovine tendon collagen and glycosaminoglycan. The collagen-glycosaminoglycan biodegradable matrix provides a scaffold for MSC retention. Preconditioning of MSC+SDR with a beta adrenergic receptor antagonist promotes and facilitates embedded or transplanted MSC survival and function better in the catecholamine rich wound microenvironment.
Current topical methods for treating DFW includes debridement to remove necrotic and infected tissues, dressings to provide a moist wound environment, bandages, and topical applications of antimicrobial or biologic agents, offloading, physical therapies, and educational strategies. However, these different treatment modalities often fail to achieve complete wound closure since they do not address the main culprit, i.e., persistent inflammation. For example, excessive use of antibiotics may address bacterial numbers and to some extent inflammation but can lead to the development of resistant strains. The present methods, compositions and kits address the inflammatory response without promoting or causing undesirable side effects like the development of antibiotic-resistant bacteria.
Subjects who can benefit generally have an epithelial and/or cutaneous wound. A wound in an epithelial tissue typically disrupts the continuity of the epithelial layer. For example, a wound in the skin typically disrupts (e.g., completely removes a section of) the epidermis, and, depending on the depth of the wound, can also remove part of the dermis. Healing of a wound in an epithelial tissue generally involves migration and/or proliferation of cells surrounding the wound, and the wound is typically considered to be healed when the wound is re-epithelialized, e.g., covered by at least one layer of cells.
In one aspect, the present extracellular matrices and methods provide for increasing the rate of repair, re-epithelialization and dermal regeneration of wounds in epithelial tissues, e.g., in humans. The methods involve the suturing, embedding and/or implanting of an extracellular matrix comprising embedded mesenchymal stem cells that have been exposed to, pre-conditioned with and/or cultured in the presence of beta adrenergic receptor antagonists to stimulate wound repair (i.e., re-epithelialization of the area), e.g., by stimulating migration and/or proliferation of epithelial cells (e.g., of keratinocytes for repair of a wound in the skin) and by decreasing the mediators of wound inflammation.
In varying embodiments, the target patient is a subject comprising or at risk for comprising a wound in an epithelial tissue. In varying embodiments, the wound is in skin. The methods and matrices described herein can be particularly useful for stimulating healing of chronic, non-healing skin wounds, which oftentimes are not sterile. In some embodiments, the wound comprises a chronic skin wound, e.g., a venous stasis ulcer, a diabetic foot ulcer, a neuropathic ulcer, or a decubitus ulcer. Other exemplary chronic wounds for which the methods can be used include, but are not limited to, other chronic ulcers such as immune-mediated (e.g., rheumatoid arthritis) ulcers, radiotherapy-induced ulcers, and ulcers resulting from vasculitis, arteriolar obstruction or occlusion, pyoderma gangrenosum, thalessemai, and other dermatologic diseases that result in non-healing wounds. In a related class of embodiments, the wound results from surgical wound dehiscence.
The methods and matrices described herein can also be applied to other types of wounds. For example, the wound can comprise a burn, cut, incision, laceration, ulceration, abrasion, or essentially any other wound in an epithelial tissue.
A wide variety of beta-adrenergic receptor antagonists are known and have been described in the scientific and patent literature, many of which are in clinical use for other conditions. Although a few exemplary antagonists are listed below, no attempt is made to identify all possible agonists and antagonists herein. Other suitable antagonists which of use can be readily identified by one of skill in the art.
In varying embodiments, the beta adrenergic receptor antagonist is selective for the β2 adrenergic receptors, affecting or antagonizing substantially only the β2 adrenergic receptors. In some embodiments, the beta adrenergic receptor antagonist is nonselective, affecting or antagonizing the β1 and β2 adrenergic receptors, the β1, β2 and β3 adrenergic receptors, or the like. It will be evident that selectivity is optionally a function of the concentration of the antagonist. For example, an antagonist can have a Ki for the β2 adrenergic receptor that is 100-fold less than its Ki for the β1 adrenergic receptor, in which example the antagonist is considered to be selective for the β2 adrenergic receptor over the β1 adrenergic receptor when used at a concentration relatively near its Ki for the β2 adrenergic receptor (e.g., a concentration that is within about 10-fold of its Ki for the β2 adrenergic receptor).
In varying embodiments, the antagonist of a beta-adrenergic receptor is a non-selective antagonist for β1 and β2 adrenergic receptors. Illustrative non-selective antagonists of beta-adrenergic receptors include without limitation, e.g., carteolol, carvedilol, dilevelol, labetalol, nadolol, penbutolol, pindolol, propranolol, sotalol, timolol, and mixtures, analogs and salts thereof. In varying embodiments, the antagonist of a beta-adrenergic receptor is a selective antagonist for β1 adrenergic receptors. Illustrative selective antagonists for β1 adrenergic receptors include without limitation from the group consisting of acebutolol, atenolol, betaxolol, bisoprolol, celiprolol, esmolol, metoprolol, nebivolol, and mixtures, analogs and salts thereof. In varying embodiments, the antagonist of a beta-adrenergic receptor is a selective antagonist for β2 adrenergic receptors. Illustrative selective antagonists for β2 adrenergic receptors include without limitation ICI 118,551 and butoxamine.
In varying embodiments, the beta adrenergic receptor antagonist can be selective or nonselective for the β2 adrenergic receptors. Similarly, in certain embodiments, the antagonist has a greater affinity for the β2 adrenergic receptors than for the β3 adrenergic receptors. Thus, in one aspect, the antagonist has a Kd for a β3 adrenergic receptor that is about 100 or more times greater than a Kd of the antagonist for a β2 adrenergic receptor. In one aspect, the antagonist is substantially free of activity as a β3 adrenergic receptor agonist, e.g., has no detectable or significant activity as a β3 adrenergic receptor agonist. For example, in some embodiments, the scaffolds and methods optionally exclude CGP 12177.
The choice of antagonist for a particular application can be influenced, for example, by factors such as the half-life of the compound, its selectivity, potential side effects, preferred mode of administration, potency, and clinical information about a given patient (e.g., any known pre-existing conditions that might be exacerbated by administration of an agonist or antagonist, potential drug interactions, or the like). Nadolol has a long half-life (on the order of 24 hours), and potentially has lower central nervous system side effects due to low lipid solubility.
The concentration of beta adrenergic receptor antagonist cultured with the MSCs or amount of antagonist to be administered to the wound can depend on several factors, including without limitation, the nature, severity, and extent of the wound to be treated, the potency of the compound, the patient's weight, the patient's clinical history and response to the antagonist, and the discretion of the attending physician. Appropriate dosage can readily be determined by one of skill in the art. In varying embodiments, MSCs pre-conditioned with or exposed to beta-adrenergic receptor antagonists and embedded in an extracellular matrix or SDR are first implanted, embedded or sutured into or onto a wound, and then subsequent additional administrations of beta-adrenergic receptor antagonists are administered to the subject, e.g., either systemically administered or locally applied directly to the wound and the extracellular matrix within or on the wound.
Follow-up administrations of the beta adrenergic receptor antagonist can be administered to the patient at one time or over a series of administrations, as appropriate. For repeated administrations over several days or longer, depending on the condition, the treatment is optionally sustained until a desired result occurs; for example, until a wound is healed. Similarly, treatment can be maintained as required. The progress of the therapy can be monitored by conventional techniques and assays.
The antagonist can be administered systemically, locally, and/or topically. For example, the antagonist can be administered systemically, e.g., orally or intravenously. As another example, the antagonist can be administered topically, e.g., by application of an ointment, cream, lotion, gel, suspension, spray, dressing, transdermal device, foam, or the like comprising the antagonist to the wound. As yet another example, the antagonist can be administered locally or intralesionally by injecting the antagonist directly into tissue underlying or immediately adjacent to the wound. For example, for a skin wound, the antagonist can be administered by injecting it subcutaneously or intradermally at or near the site of the skin wound. In varying embodiments, the beta adrenergic receptor antagonist is directly attached to the extracellular scaffold matrix, e.g., via covalent bonding or crosslinking. Crosslinkers of use are known in the art. In varying embodiments, the beta adrenergic receptor antagonist is directly attached or crosslinked to the extracellular scaffold matrix using a linkage chemistry or integrated biodegradable matrix (e.g., Poly(D,L-lactide-co-glycolide (PLGA) beads).
A pharmaceutical composition for topical administration of a beta adrenergic receptor antagonist, e.g., an ointment, cream, lotion, foam, or gel (e.g., an aqueous gel), or, in general, a solution or suspension of the agonist or antagonist, typically contains from 0.01 to 10% w/v (weight/volume, where 1 g/100 ml is equivalent to 1%) of the agonist or antagonist, preferably from 0.1 to 5% w/v, e.g., mixed with customary excipients or dissolved in an appropriate vehicle for topical application. Exemplary compositions formulated for topical application to skin can comprise an ointment (e.g., an occlusive or petrolatum-based ointment), cream, lotion, gel, spray, foam, or the like, e.g., in which the antagonist is suspended, dissolved, or dispersed. Many suitable bases for such ointments, creams, lotions, gels, etc. are known in the art and can be used. At least one component of the composition is optionally insoluble in water and/or hydrophobic; for example, the composition optionally includes an oil (e.g., a suspension of an oil in water), petrolatum, a lipid, or the like.
In a pharmaceutical composition for oral, sublingual, subcutaneous, intramuscular, intravenous, transdermal, or local administration, for example, the agonists or antagonists can be administered in unit forms of administration, either as such, for example in lyophilized form, or mixed with conventional pharmaceutical carriers. Appropriate unit forms of administration include oral forms such as tablets, which may be divisible, gelatin capsules, powders, granules and solutions or suspensions to be taken orally, sublingual and buccal forms of administration, subcutaneous, intramuscular or intravenous forms of administration, and local forms of administration.
When a solid composition is prepared in the form of tablets, the main active ingredient is optionally mixed with a pharmaceutical vehicle such as gelatin, starch, lactose, magnesium stearate, talcum, gum arabic or the like. The tablets can be coated with sucrose or other appropriate substances, or can be treated so as to have a prolonged or delayed activity and so as to release a predetermined amount of active principle continuously. A preparation in the form of gelatin capsules can be obtained by mixing the active ingredient with a diluent and pouring the resulting mixture into, soft or hard gelatin capsules. A preparation in the form of a syrup or elixir optionally contains the active ingredient together with a sweetener, antiseptic, flavoring and/or appropriate color. Water-dispersible powders or granules can contain the active ingredient mixed with dispersants, wetting agents or suspending agents, as well as with sweeteners or taste correctors. Suppositories (e.g., for vaginal or rectal administration) can be prepared with binders melting at the appropriate (e.g., vaginal or rectal) temperature. Parenteral administration is typically effected using aqueous suspensions, saline solutions or injectable sterile solutions containing pharmacologically compatible dispersants and/or wetting agents. The antagonist is optionally encapsulated in liposomes or otherwise formulated for prolonged or delayed release, e.g., whether for topical, local, and/or systemic administration.
In varying embodiments, the MSCs are exposed to a concentration of beta adrenergic receptor antagonist sufficient to supersede or overcome signaling through Toll-Like receptors (e.g., TLR2) facilitating the concomitant prevention, reduction and/or inhibition of the production of IL-6 and other inflammatory mediators that inhibit wound healing. In varying embodiments, the MSCs are exposed to, cultured in or preconditioned with a concentration of at least about 0.1 μM to about 50 μM beta adrenergic receptor antagonist, e.g., from at least about 1.0 μM to about 25 μM beta adrenergic receptor antagonist, e.g., from at least about 1.0 μM to about 10 μM beta adrenergic receptor antagonist. In varying embodiments, the MSCs are exposed to, cultured in or preconditioned with a concentration of at least about 0.2 μM to about 50 μM, e.g., about 0.4 μM to about 40 μM, e.g., about 0.3 μM to about 30 μM, e.g., about 0.2 μM to about 20 μM, e.g., about 1.0 μM to about 10 μM. In varying embodiments, MSCs within the extracellular matrix may have continued exposure to the beta adrenergic receptor antagonist. In varying embodiments, the beta adrenergic receptor antagonist is added to the matrix or culture medium one or multiple times, as needed to promote, facilitate and/or accelerate wound healing.
The methods and extracellular matrices described herein entail the administration to a wound of MSCs that have been contacted and/or pre-conditioned with and/or exposed to a beta adrenergic receptor antagonist. Data provided herein and in Dasu, et al., Stem Cells Transl Med. (2014) 3(6):745-59 (hereby incorporated herein by reference in its entirety for all purposes) demonstrate that exposing MSCs to a beta adrenergic receptor antagonist promotes and/or facilitates wound healing.
The bone marrow of an adult mammal is a repository of mesenchymal stem cells (MSCs). These cells are self-renewing, clonal precursors of non-hematopoietic tissues. MSCs for use in the present methods can be isolated from a variety of tissues, including bone marrow, muscle, fat (i.e., adipose), liver and dermis, using techniques known in the art. Illustrative techniques are described herein and reported in, e.g., Chung, et al., Res Vet Sci. (2010) November 12, PMID:21075407; Toupadakis, et al., American Journal of Veterinary Research (2010) 71(10):1237-1245.
Generally, the MSCs useful for administration express on their cell surface CD44 and CD90 and do not express on their cell surface CD34, CD45, CD80, CD86 or MHC-II. In various embodiments, the MSCs are adipose-derived mesenchymal stem cells (Ad-MSC). Ad-MSCs can be characterized by the surface expression of CD44, CD5, and CD90 (Thy-1); and by the non-expression of CD34, CD45, MHC class II, CD3, CD80, CD86, CD 18 and CD49d. In other embodiments, the MSCs are derived from a non-adipose tissue, for example, bone marrow, liver, lacrimal gland, and/or dermis. In some embodiments, the MSCs are non-haematopoietic stem cells derived from bone marrow (i.e., do not express CD34 or CD45).
As appropriate, the MSCs can be autologous (i.e., from the same subject), syngeneic (i.e., from a subject having an identical or closely similar genetic makeup); allogeneic (i.e., from a subject of the same species) or xenogeneic to the subject (i.e., from a subject of a different species).
In various embodiments, the MSCs may be altered to enhance the viability of the embedded, engrafted or transplanted cells. For example, the MSCs can be engineered to overexpress or to constitutively express Akt. See, e.g., U.S. Patent Publication No. 2011/0091430.
In various embodiments, embedding, engraftment or transplantation of the beta adrenergic receptor antagonist-conditioned MSCs is facilitated using a matrix or caged depot, e.g., an extracellular matrix scaffold. For example, the MSCs can be embedded, engrafted or transplanted in a “caged cell” delivery device wherein the cells are integrated into a biocompatible and/or biologically inert matrix (e.g. a hydrogel or other polymer or any device) that restricts cell movement while allowing the cells to remain viable. Synthetic extracellular matrix and other biocompatible vehicles for delivery, retention, growth, and differentiation of stem cells are known in the art and find use in the present methods. See, e.g., Prestwich, J Control Release. 2011 Apr. 14, PMID 21513749; Perale, et al., Int J Artif Organs. (2011) 34(3):295-303; Suri, et al., Tissue Eng Part A. (2010) 16(5):1703-16; Khetan, et al., J Vis Exp. (2009) October 26; (32). pii: 1590; Salinas, et al., J Dent Res. (2009) 88(8):681-92; Schmidt, et al., J Biomed Mater Res A. (2008) 87(4):1113-22 and Xin, et al., Biomaterials (2007) 28:316-325. The extracellular matrix can be naturally occurring (e.g., decellularized tissue) or synthetic.
Any biocompatible, biodegradable matrices known in the art can be used as a scaffold or extracellular matrix for the MSCs. In varying embodiments, the matrix is made of naturally derived components (e.g., collagen, elastin, laminin, gelatin and/or other naturally derived materials). In varying embodiments, the matrix can be synthetic or made of or comprise non-naturally derived components. Biocompatible, biodegradable materials useful in the matrices include, e.g., polyglycolic acid (PGA), type 1 collagen, Poly-DL-lactide-caprolactone (PCL), laminin, gelatin, chitin, alginate, keratin, and the like. In varying embodiments, the matrix comprises collagen. Illustrative extracellular matrices that are commercially available and find use include without limitation, e.g., matrices available from Integra Life Sciences (integralife.com); Oasis Wound matrices available from Cook Biotech (oasiswoundmatrix.com); MatriStem matrices from ACell (acell.com); GRAFTJACKET® matrices from Wright Medical Technology (wmt.com); MatriDerm® matrices by MedSkin Solutions Dr. Suwelack AG (medskin-suwelack.com); and UNITE™ Biomatrices by Baxter Healthcare (synovissurgical.com).
As appropriate or desired, the embedded, engrafted or transplanted beta adrenergic receptor antagonist-conditioned MSCs can be modified to facilitate retention of the MSCs at the region of interest or the region of delivery, e.g., at the site of the wound. In other embodiments, the region of interest for embedding, engraftment or transplantation of the cells is modified in order to facilitate retention of the MSCs at the region of interest or the region of delivery. In one embodiment, this can be accomplished by introducing stromal cell derived factor-1 (SDF-1) into the region of interest, e.g., using a linkage chemistry or integrated biodegradable matrix (e.g., Poly(D,L-lactide-co-glycolide (PLGA) beads) that would provide a tunable temporal presence of the desired ligand up to several weeks. MSCs bind to the immobilized SDF-1, thereby facilitating the retention of MSCs that are delivered to the region of interest for embedding, engraftment or transplantation. In other embodiments, integrating cyclic arginine-glycine-aspartic acid peptide into the region of interest can facilitate increased MSC binding and retention at the region of interest for embedding, engraftment or transplantation. See, e.g., Ratliff, et al., Am J Pathol. (2010) 177(2):873-83.
In varying embodiments, at least about 0.25×106 MSCs are provided to the subject, e.g., in the matrix embedded, engrafted or implanted at the site of the wound. As appropriate, the number of MSCs injected into the subject or embedded, engrafted or implanted into the matrix at the site of the wound can be at least about, e.g., 1×104 cells, 2.5×104 cells, 5×104 cells, 7.5×104 cells, 1×105 cells, 2.5×105 cells, 5×105 cells, 7.5×105 cells, 1×106 cells, 2.5×106 cells, 5×106 cells, 7.5×106 cells, 1×107 cells, 2.5×107 cells, 5×107 cells, 7.5×107 cells, or 1×108 cells.
In various embodiments, the cells can be delivered or embedded in the extracellular matrix at a concentration in the range of about 1×106 cells/ml to about 1×108 cells/ml, for example, in the range of about 5×106 cells/ml to about 5×107 cells/ml, for example about 1×106 cells/ml, 5×106 cells/ml, 1×107 cells/ml, 5×107 cells/ml or 1×108 cells/ml.
The total amount of cells that are envisioned for use depend upon the desired effect, patient state, and the like, and may be determined by one skilled within the art. Dosages for any one patient depends upon many factors, including the patient's species, size, body surface area, age, the particular MSCs to be administered, sex, scheduling and route of administration, general health, and other drugs being administered concurrently.
The following examples are offered to illustrate, but not to limit the claimed invention.
Mesenchymal Stem Cells (MSC).
Human bone marrow aspirations obtained from four healthy donors were purchased from Lonza. MSC were harvested from bone marrow (BM) following established protocols (26, 27), and used between passages 3-5. Characterization of MSC included differentiation into osteogenic and adipogenic lineage cells, as described previously (27). The stem cell research oversight (SCRO) review board at the University of California, Davis approved all the human cell protocols.
Neonatal Human Keratinocytes (NHK).
NHK were isolated from human neonatal foreskins, cultured and maintained, as reported earlier (28,29). NHKs isolated from at least three different foreskins and between passages 3 and 7 were used in all the experiments. The Institutional Review Board at UC Davis approved the protocol for obtaining discarded neonatal foreskins.
Cell treatments.
Epinephrine (EPI: Sigma) and TLR2 ligands (macrophage activating lipoprotein-2: MALP2—that specifically activates TLR2/6 heterodimerization, and heat killed Staphylococcus aureus: HKSA; Invivogen) treatments were carried out at the indicated times and concentrations. All the cells were maintained in 0.5% fetal bovine serum containing culture medium overnight prior to treatment. Cells were exposed to different treatments in fresh serum-free medium. In some experiments, cells were pretreated for 30 minutes with Timolol (10 μM; Sigma) or ICI-118, 551 (ICI; 10 μM; Tocris) followed by EPI and MALP2 treatment as described previously (11-13, 30).
Single-Cell Migration.
NHK and BM-MSC were plated on collagen I-coated plates as reported previously (11-13,30). Time-lapse images of the cell migration were captured every 5 minutes for 1 hour. The distance cells travel in a one-hour time period is recorded and indicated as the average speed (μm per minute). Significance was set at P<0.05, and Student's t test (unpaired) was used to compare the means of two cell populations as reported previously (11-13, 30).
Animals with EPI Osmotic Pumps and Full-Thickness Cutaneous Wounds.
C57BL/6J (male; 8-10 week age; Jax Mice) with ad libitum access to food and water were anesthetized using isoflurane and one 6 mm circular diameter full-thickness wound was placed on the dorsal shaved skin β1). Micro-osmotic pumps (0.25 μl/hour; Alzet micro-osmotic pump Model: 1002, Alzet) were implanted on the right flank of the mice to deliver 7 mg/kg body weight/day EPI and 0.7 mg/kg body weight/day of ICI) as we have previously reported (11-13,30). At 7 or 11 days after injury, the mice were euthanized, the wound tissue was harvested by 8 mm punch excision and stored frozen or formalin—fixed until further analysis. Animal protocols were approved by the IACUC at UC Davis.
Real Time PCR (RT-PCR).
mRNA expression was determined by real-time PCR (RT-PCR), using sequence-specific primers and probes. Total RNA was extracted from the cells using Qiagen RNeasy mini kit. The first strand of cDNA was synthesized using 1 μg of total RNA. cDNA (50 ng) was amplified using primer probe sets for TLR2, beta-2-adrenergic receptor (ADRB2) and three housekeeping genes: beta-2-microglobulin, GAPDH, and RPLPO using standard cycling parameters. Data were calculated using the 2-ΔΔCt method and are presented as fold change (ratio of transcripts of gene normalized to the three house-keeping genes) (11-13, 31).
ELISA.
Levels of interleukin-6 (IL-6) were measured with an ELISA kit (R&D systems). IL-6 levels were normalized to total cell protein and expressed as pg/μg protein β1).
Western Blots.
Twenty five μg of total protein was resolved, transferred, and probed with antibodies for β2-AR (Abcam), phospho beta-adrenergic receptor activated kinase-1 (BARK-1/GRK2 referred to as BARK-1 from here after; GeneTex), TLR2 (Imgenex) Myeloid differentiation factor 88 (MyD88; Imgenex), phospho interleukin receptor activated kinase-1 (pIRAK-1 and IRAK-1; Cell Signaling), phospho ERK1/2 (Santacruz), phenylethanolamine N-methyltransferase (PNMT) and tyrosine hydroxylase (TH), and stripped membranes were further incubated with respective total antibodies or GAPDH or α-tubulin. TLR2 (Imgenex) and β2-AR (Santacruz) antibodies were used for co-immunoprecipation assays and antibody protein complexes were further probed with above antibodies β1). Protein A/G-sepharose beads and isotype matched IgG antibodies were used as negative controls in all the co-immunoprecipitation experiments along with the antibody used for the pull down as a positive control. Band intensities were determined as described previously and normalized to GAPDH/α-tubulin or total protein (BARK-1) and densitometric ratios are presented as fold change vs control β1). For some experiments, cell lysates from three independent experiments were pooled to get enough protein for the assay and repeated three times for densitometry purposes.
Scratch Wound Assays.
The rate of healing scratch wounds made in confluent NHK cultures was determined as reported previously (30, 32). Briefly, cells were pretreated with 10 μg/ml mitomycin (EMD Millipore) for 1 hr to inhibit cell proliferation that could skew the data analysis. Wounded cultures were incubated in growth medium (control) containing EPI, TLR2 ligands, and/or Timolol or ICI. Velocity Image analysis software (Perkin Elmer) was used to measure the scratch wound area, which is expressed as percent closed wound.
HPLC Detection of Catecholamines.
Cell culture samples from at least from three independent experiments were acidified with perchloric acid to 0.2N prior to storage at −80° C. for future analysis. The supernatant were applied to conditioned MonoSpin® PBA solid phase extraction spin columns (GL Sciences) and purifications were performed according to the manufacturer's specifications. Catecholamines were eluted in 200 μL of 2% acetic acid.
HPLC separation was performed using a Synergi™ 4 um Fusion-reverse phase 250×4.6 mm column (Phenomenex) and a HP series 1050 pump and auto injector system. The mobile phase for chromatographic separation was a modification of that used by Leis et al (33). Detection of catecholamine compounds was performed using a LC-4C amperometric detector (Bioanalytical Systems) using potential of −700 mV. Catecholamine levels are presented as pg/μg cell protein.
Statistical Analysis.
Statistical analyses were performed using Excel and Graphpad Prism. Data are expressed as mean±S.D. Parametric data were analyzed using paired, two tailed t-tests and non-parametric data using Wilcoxon signed rank tests. Level of significance was set at P<0.05 (11-13, 30, 31).
1. EPI Induces TLR2 Expression and Signaling; Conversely TLR2/6-Specific Ligand MALP2 Upregulates β2-AR mRNA and Protein Expression in BM-MSC.
To address the question of how EPI stress impacts upon innate immune capabilities of BM-MSC, we examined the effect of EPI treatment on TLR2 expression and IL-6 secretion. EPI significantly induced IL-6 secretion in BM-MSC with maximal induction at 50 nM (
EPI significantly increased TLR2 expression in BM-MSC, both at the mRNA (
The question of whether TLR2 signaling could impact upon the β2-AR system is one we explored here. We examined whether the TLR2 agonist MALP2 could modulate the β2-adrenergic signaling cascade. Both mRNA and protein expression for the β2-adrenergic receptor are significantly up-regulated in BM-MSC treated with MALP2 (
In murine macrophages, specific TLR ligands have been shown to increase BARK-1 protein expression (39), a downstream event generally ascribed to β2-AR stimulation (40-42). To determine if MALP2 activation of the TLR2 could also result in synergistic downstream signaling through the β2-AR pathway, we examined the phosphorylation of BARK-1 (39). MALP2 stimulation of BM-MSC significantly increased BARK-1 phosphorylation (
Migration of MSC to the wound site (18, 20, 21) and NHK migration for wound re-epithelialization (22) are both critical for optimal healing. Therefore, we addressed the question of how β2-AR and TLR cross-talking pathways could affect migration in these two cell types. EPI treatment reduced BM-MSC migratory speed by 10% (
We investigated the downstream convergence of these two distinct receptor-signaling systems by measuring the release of the inflammatory cytokine, IL-6 from cells treated with EPI or MALP2. Both agents induced significant increases (3.8 and 2.6 fold, respectively) in IL-6 secretion in BM-MSC as compared to untreated control cells (
Next, we asked the question of whether blocking one of the receptors (β2-AR) could effectively increase cell migration and decrease IL-6, both critical for improved healing. β-blockers are being used clinically to improve outcomes in burn wound patients (49,50), and improve healing in chronic wounds (51,52). We selected the β1/2-AR antagonist, Timolol, that has been shown to reverse β2-AR inhibition of keratinocyte migration (32) and is a currently FDA approved drug. Pretreatment of cells with Timolol (10 μM, 30 min) reversed the EPI+MALP2 or EPI+HKSA synergistic effects on the cell migration and IL-6 release in BM-MSC and NHK. Timolol pretreatment reversed EPI+MALP2 effects on BM-MSC migration (EPI+MALP2: 21% inhibition vs. T+Epi+MALP2: 8.7% inhibition; P<0.001) (
The antagonist effect of Timolol on IL-6 release was observed in both BM-MSC and NHK. Levels of IL-6 were three fold higher in HKSA treated BM-MSC and NHK compared to MALP2 treatment (
Using co-immunoprecipitation assays with β2-AR and TLR2 antibody, we demonstrated the association between β2-AR-TLR2-MyD88-IRAK-1 and TLR2-β2-AR-BARK-1 signaling in MALP2 and EPI treated NHKs (
The work presented above demonstrates that activation of the adrenergic receptor in the presence of TLR ligands can upregulate the TLR-mediated immune response, and conversely, that activation of TLR by its bacterially-generated ligands cross-talks to activate signaling through the adrenergic receptor pathway. Here we ask the related question of whether the bacterial (TLR2) ligands can further contribute to adrenergic receptor signaling response by increasing secretion of their catecholamine ligands by wound-resident cells. We found that EPI and norepinephrine levels in the cell culture supernatants of MALP2 treated BM-MSC and NHK (
Since keratinocyte migration from the wound edge is critical for healing, we used a scratch wound assays to determine if EPI and MALP2 can modulate NHK mobility in a wound environment (30, 56). EPI and MALP2 decrease NHK scratch wound closure (Control: 37% closed, EPI+MALP2: 9.3% closed, P<0.05) while the addition of antagonists reverses this effect (T+EPI+MALP2: 23% closed;
To determine if the observed in vitro effects of EPI-induced TLR2 expression, signaling, and wound healing in BM-MSC and NHK translated to the in vivo situation, we used a pharmacologic model of sustained EPI stress to impair healing in mice (13,30). Wound closure was significantly decreased in EPI stressed mice compared to control mice and was reversed in animals treated with the β2-AR antagonist ICI (
The ability of catecholamine stress to impair healing has been well documented with mechanisms of impairment ascribed to alteration in keratinocyte and fibroblast function (11-13) as well as prolongation of neutrophil persistence in the wound (60). Here we present data to demonstrate a novel mechanism by which EPI stress synergizes with innate immune receptor (TLR2) function in BM-MSC and keratinocytes to generate a pro-inflammatory environment that can ultimately impair wound healing. Cross-talk between the adrenergic receptors (AR) and the TLRs present on these cell types result in their impaired ability to migrate, as well as upregulated generation of the pro-inflammatory cytokine IL-6. Interestingly, we find that EPI activation of the AR can induce increased TLR2 receptor expression, activation and downstream signaling, and conversely, TLR2 activation, either by the agonist MALP2 or by bacteria, can induce increased β2-AR receptor expression, activation and downstream signaling. Activation of either the β2-AR or the TLR2 receptor results in the physical association of the two receptors and their proximal downstream effectors, mechanistically providing a signaling platform for the cross-talk. Concurrent activation of the AR and TLR pathways results in synergistic effects on cell migration and inflammation. These deleterious effects are amplified by an autocrine loop, wherein TLR activation results in increased synthesis of EPI by upregulation of catecholamine synthetic enzymes in both keratinocytes and BM-MSC. Thus, the present work describes a new paradigm for functional interplay between stress hormones and bacterial ligands wherein the dual ligand signaling results in cross activation of both the adrenergic receptor system and the innate immune/inflammatory pathways in MSC, with resultant potential deleterious consequences for healing (
Systemic levels of the catecholamine stress hormones, EPI and norepinephrine, are several fold elevated above physiologic levels during anxiety, pathogenic challenge, or injury and trauma (8-10). These ligands are agonists for the adrenergic receptors (α and β-AR) that are expressed on all immune competent cells (61) including those involved in innate immune responses (62-64). While much of the earlier literature supported the notion that activation of the β2-AR suppresses immune response and inflammation (65), emerging literature has shown that AR activation can result in pro-inflammatory responses from the immune system. For example, activation of β2-AR has been shown to be responsible for inflammatory immune cell responses characterized by increased cytokine (IL-1β, IL-6, TNF-α) production (66, 67). Furthermore, activation of the β2-AR with salmeterol in the RAW 264.7 macrophages resulted in 80- and 8-fold increase in IL-1β and IL-6 transcripts, respectively, accompanied by a significant increase in IL-1β and IL-6 protein production (40). Local elevation of IL-6 levels in the wound, mediated by catecholamine activation of the β2-AR in wound macrophages, results in increased dwell time of neutrophil trafficking to the wound, thus delaying healing (60). Thus, AR activation on immune cells is associated with variable local pro-inflammatory factor release and may affect the wound healing process.
MSCs are another cell type with potent immuno-modulatory capacity. These cells are recruited to a wound or site of injury (20,21) and can attract immune inflammatory cells (68,69). Interestingly, murine MSCs express a full repertoire of AR, including β1, β2, β3 (70-72). Their activation has been previously investigated primarily in the realm of MSC lineage commitment (70-72) and to some extent for the ability to impact upon their immune orchestrating abilities. Since both keratinocytes and MSC express AR, and both are critical for wound repair, we chose to investigate how activation of these receptors by their stress-induced catecholamine ligands could impact on functions critical for healing, such as migration and inflammation.
Like ARs, TLRs play a crucial role in the wound biology and innate immunity. TLRs activation constitutes one of the earliest responses of an organism to microbial invasion (73,74). We, and others, have demonstrated that prolonged stimulation of TLRs leads to increased inflammation with a corresponding decrease in the ability to heal (31, 75). Of note, an increasing body of evidence indicates that catecholamines can modulate innate cytokine responses with increased expression of pro-inflammatory cytokines (66, 76). For instance, EPI can upregulate LPS-stimulated human monocytic cytokine responses (via TLR4, IL-12, TNF-α-, and IL-10) (66). In murine macrophages, epinephrine pretreatment significantly increases TNF-α production with LPS stimulation and this effect is mitigated by blockade of either the α2-AR or β2-AR (10). These effects can be very cell type and species specific since the reverse finding, of a β2-AR agonist mediated decrease in TLR innate immune responses, has also been reported (77). In a monocytic cell line and in rat macrophages, exposure to supraphysiologic levels of EPI (5000-10,000 ng/ml) decreases TLR4 mRNA expression (78, 79). All of these studies focused on TLR4 responses, mostly mediated by gram-negative bacterial ligands (LPS). However, the major isolates within chronic wounds are gram-positive bacteria (ex. Staphylococcus aureus, 46-48) and thus to maintain physiological relevance, we examined the effects of EPI on TLR2 (activated by MALP2 or S. aureus; 35-37, 45) in human MSC and keratinocytes.
Given the important physiological roles for both TLR2 and β2-ARs in wound biology and the regulatory role of BARK-1 in β2-AR downstream signaling, we examined the hypothesis that TLR2 activation modulates BARK-1 phosphorylation. We found that EPI increased BARK-1 phosphorylation in BM-MSC, as might be expected. More surprisingly, however, is the finding that activation of TLR2 with MALP2 also increased BARK-lphosphorylation both in BM-MSC and NHK. Although earlier studies in murine peritoneal macrophages (39) have suggested that the mechanisms for TLR ligand induced BARK-1 expression is regulation at both transcriptional and post-transcriptional levels (39) and our findings demonstrate that there may be a physical association between β2-AR and TLR2 receptors and the possibility of a cross activation by the respective ligands at the receptor and signaling levels. Furthermore, our results may explain findings in other inflammatory disease processes. For example, an increase in BARK-1 expression was observed in neutrophils obtained from septic humans relative to those of healthy individuals (79), sepsis being a condition associated with both activation of TLR and AR (80,81) by high systemic levels of stress catecholamines and bacterial derived ligands (8-10, 34, 80, 81). These results support our hypothesis that a combination of catecholamine stress and signaling through the innate immune intracellular transduction pathway result in an exaggerated inflamed local environment, characteristic of chronic wounds.
In 1994, Bergquist et al (82) demonstrated the presence of endogenous catecholamines in lymphocytes and provided evidence for an autocrine regulation of catecholamine synthesis in non-neuronal cells. A decade and half later, Flierl and colleagues showed that phagocyte-derived catecholamines enhance injury (61, 83). The authors demonstrated that exposure of phagocytes to LPS led to an increase in catecholamine release with corresponding changes in the catecholamine enzymatic generating machinery and suggested that regulation of catecholamine generation and degradation may alter the release of proinflammatory mediators in cells (62,84). In line with these two pioneering studies, we now show that both BM-MSC and NHK may serve as new sources for non-neuronal catecholamine generation within a wound environment. The autocrine loop generated by TLR activation on either BM-MSC or keratinocytes has the potential to locally generate EPI that then can amplify the inflammatory response by promoting release of IL-6.
Here we show how EPI and TLR2 ligands potentiate proinflammatory IL-6 production via the β2-AR/BARK-1 or TLR2-MyD88 signaling pathway, and that β2-AR antagonists reverse the inflammatory cytokine production and the migration defects in cells exposed to both receptors' ligands. Isolated cells in culture often respond differently than do those same cell types within a complex tissue environment. To determine if our observations translate to the in vivo environment, we examined wounds in EPI-stressed mice. Healing was impaired in the EPI-stressed animals, and the impairment reversed by blockade of the β2-AR. Wound tissues of the EPI-stressed animals demonstrate increased TLR2 expression, as well as increased IL-6 levels relative to unstressed animals. These finding provide a framework for the development of therapeutic strategies that could selectively regulate inflammatory responses in the impaired healing wound.
Indeed, several studies have already reported that treatment with β2-AR blockers improves outcomes, such as decreased pro-inflammatory cytokine secretion and improved immune cell function, in patients who have endured an operative or traumatic injury (10, 84-88). Improved healing in chronic skin wounds has also been reported using topical application of β-AR antagonists (51, 89). The mechanisms underlying the noted improved outcomes have only been partially explained. However, our study provides additional mechanistic insights by using pharmacological and biochemical approaches to characterize the signal-transduction properties of the synergistic relationship between β2-AR and TLR2 activation that results in an amplified IL-6 response. The synergistic IL-6 effect shown in our study depends on β2-AR stimulation as evidenced by a reversal of this response by either of two different β2-AR antagonists (Timolol and ICI;
The presence of bacteria in chronic wounds can influence the balance between successful and adverse healing outcomes. Staphylococcus aureus is noted to be the pathogen harbored by the great majority of chronic wounds (45-48, 90). In addition to bacterial presence in wounds, many wounds are in a high catecholamine environment. In particular, patients with burn wounds and chronic inflammatory diseases have elevated levels of catecholamines (8-10, 13). Although both catecholamine stress and TLR2 activation individually contribute to the chronic wound pathology there are no studies linking the two. Our study makes this connection with wide ranging clinical implications for persistent inflammation, stress, and infection.
In conclusion, we have shown that EPI-mediated activation of the innate immune receptor TLR2, IL-6 production, and impaired wound healing might represent a previously unrecognized hormonal, immunological mechanism that is involved in shaping the roles of BM-MSC and NHK in the wound healing process. This neuroendocrine mechanism may play a critical role in driving innate immune receptor profiles in wounds with intrinsic overexpressed catecholamines. Thus, in the infected wounds, migrating and resident cells react to bacterial ligands/infection by inducing catecholamine production and potentiate persistent inflammation creating an impaired healing phenotype. Our findings have implications for the hormonal innate immune receptor interactions and for understanding the mechanisms controlling the differing susceptibility to infections and immune/inflammatory-related conditions in wounds.
It is understood that the examples and embodiments described herein are for illustrative purposes only and that various modifications or changes in light thereof will be suggested to persons skilled in the art and are to be included within the spirit and purview of this application and scope of the appended claims. All publications, patents, and patent applications cited herein are hereby incorporated by reference in their entirety for all purposes.
This application is a U.S. national phase filing under 35 U.S.C. §371 of Intl. Appl. No. PCT/US2014/051723, filed on Aug. 9, 2014, which claims the benefit under 35 U.S.C. §119(e) of U.S. Provisional Application No. 61/870,766, filed on Aug. 27, 2013, each of which are hereby incorporated herein by reference in their entireties for all purposes.
Filing Document | Filing Date | Country | Kind |
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PCT/US2014/051723 | 8/19/2014 | WO | 00 |
Number | Date | Country | |
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61870766 | Aug 2013 | US |