Treatment and/or prevention of sepsis

Abstract

The disclosure provides molecules with an affinity for (or an ability to bind to), sialic acid, for use in compositions, medicaments and methods for the treatment of sepsis, its symptoms and sepsis associated pathologies and immune responses.

Description

STATEMENT OF PRIORITY

This application is a 35 U.S.C. § 371 national phase application of International Application Serial No. PCT/GB2017/052800, filed Sep. 20, 2017, which claims the benefit, of United Kingdom Patent Application No. 1616009.5, filed Sep. 20, 2016, the entire contents of each of which are incorporated by reference herein.

FIELD OF THE INVENTION

The invention provides molecules for use in compositions, medicaments and methods for the treatment of sepsis, its symptoms and sepsis associated pathologies and immune responses.

BACKGROUND OF THE INVENTION

Sepsis is a life-threatening condition that is most commonly caused by bacteria in the bloodstream, a condition known as bacteraemia. Pathogenic bacteria originating from a primary infection location, such as the lungs or urinary tract, release toxins that can provoke a dysregulation of the innate immune response, leading to host tissue and organ damage¹.

Bacterial sepsis is a worldwide problem, generally resulting from nosocomial polybacterial infections, and is responsible for 25% intensive care admissions with a survival rate of around 50%².

While conventional antibiotics may be effective in killing pathogenic microorganisms in sepsis patients, they can also accelerate the release of pro-inflammatory components causing severe sepsis and shock. Alternative compounds of interest for sepsis therapy include natural occurring antimicrobial peptides (AMPs), which target pathogenic bacteria and fungi by displaying different defense mechanisms such as membrane disruption, with some having immunomodulatory activities⁴. AMPs mainly function by disabling/killing pathogen without releasing pro-inflammatory agents. However, there are several challenges with the use of AMPs as therapeutics due to their limited pharmaceutical application such as high toxicity in most tissues, as well as the likelihood of microbial resistances. Attempts to design synthetic based AMPs to reduce toxicity and stability issues are in developments.

Multivalent Family 40 CBMs (mCBM40s) target and bind to host cell surface sialic acid receptors with high affinity^7,8. These engineered mCBM40s also display immunomodulatory activities when given intranasally either alone, or in respiratory pathogen-challenged mouse models^5,9.

Despite the use of antibiotics as a control strategy for bacterial sepsis, the rise in antibiotic resistance by bloodstream bacterial isolates in recent years has highlighted an urgent need for novel compounds, therapies and regimes for the treatment and management of sepsis, its symptoms and pathologies³.

SUMMARY OF THE INVENTION

The present disclosure is based on the finding that molecules with affinity for (or an ability to bind to) sialic acid and in particular sialylated cell surfaces (these including cell surface sialic acid receptors), find utility in the treatment and/or prevention of sepsis.

As such, the present disclosure provides a sialic acid binding molecule for use in the treatment and/or prevention of sepsis and/or one or more symptoms thereof. Further provided is the use of a sialic acid binding molecule in the manufacture of a medicament for use in the treatment and/or prevention of sepsis and/or one or more symptoms thereof.

It should be understood that throughout this specification, the terms “comprise”, “comprising” and/or “comprises” is/are used to denote aspects and embodiments of this invention that “comprise” a particular feature or features. It should be understood that this/these terms may also encompass aspects and/or embodiments which “consist essentially of” or “consist of” the relevant feature or features.

The disclosure also relates to a method of treating or preventing sepsis and/or one or more symptoms thereof, said method comprising the steps of administering to a subject in need thereof, a therapeutically effective amount of a sialic acid binding molecule.

The term “sepsis” is applied to a number of diseases, conditions and/or syndromes which may have an infectious (for example viral, bacterial and/or fungal) aetiology. For example, term “sepsis”, may embrace those disease states, conditions or syndromes referred to as SIRS (systemic inflammatory response syndrome: indicated by the presence of two or more of abnormal body temperature, heart rate, respiratory rate or blood gas and white blood cell count), sepsis (which is often defined as “SIRS in response to an infectious process”), severe sepsis (that is sepsis with sepsis-induced organ dysfunction or tissue hypoperfusion (which itself might manifest as hypotension, elevated lactate or decreased urine output) and septic shock (severe sepsis plus persistently low blood pressure despite, for example, the administration of intravenous fluids).

The term “sepsis” is most often applied to diseases, conditions and/or syndromes which result from “bacterial sepsis”. Bacterial sepsis may stem from the presence of bacteria in blood and may sometimes be referred to as “bacteraemia” or “septicemia”. The term “sepsis” may also embrace diseases and/or conditions which are caused or contributed to by the presence of bacterial components such as LPS, toxins and/or membrane fragments in the blood. Components of this type may originate from primary infections present in other tissues and/or organs, for example, infections present in the lungs, brain, skin, urinary tract, pelvis and/or abdomen.

Sepsis can be a very severe condition which occasionally leads to multiple organ failure and death. There may be a number of pathologies and/or symptoms associated with each type of sepsis and these will be collectively referred to hereinafter as “sepsis associated pathologies”. For example, sepsis associated pathologies may include, for example, fever, increased heart rate, increased rate of respiration and/or low blood pressure.

The primary mechanism which underpins the pathology of sepsis and many of the symptoms and outcomes associated therewith is an exacerbated, exaggerated and/or inappropriate host immune response. This exacerbated immune response (which is the body's response to infection) leads to host tissue damage and/or organ damage/failure.

The exacerbated or inappropriate immune response may include the dysregulation of innate immune responses as well as the production and/or over production of certain pro-coagulation cytokines (including, for example, tumour necrosis factor, interleukin 1 and interleukin 6).

The term “subject” or “subject in need thereof” as used herein, may embrace any subject who has or is at risk of developing “sepsis”. For example, the subject may be one who is predisposed or susceptible to sepsis. The “subject” may be one who has been diagnosed as suffering from one or more of the “sepsis” type pathologies described herein. The “subject” may be one who has an infection and who may go on to develop sepsis.

It should be understood that the various “sepsis” associated pathologies described above include conditions, syndromes and/or effects that may otherwise be described as “symptoms” of sepsis. As such, one or more of the sialic acid binding molecules described herein may be for use in the treatment and/or prevention of any (one or more) of these symptoms. For example, this disclosure provides any one or more of the sialic acid binding molecules described herein, for use in the treatment and/or prevention of sepsis associated:fever; immune response(s); low blood pressure; increased heart rate and/or increased rate of respiration.

Further, any of the sialic acid binding molecules described herein may be used in the manufacture of medicaments and methods for treating or preventing the same.

Without wishing to be bound by theory, it is suggested that the sialic acid binding molecules described herein are effective to dampen, suppress or inhibit the pro-inflammatory cytokine cascade that is a pre-cursor to sepsis or one or more of the symptom(s) thereof. Nevertheless, it is also suggested that the sialic acid binding molecules described herein (including the CBM-type molecules) can be used to prevent the invasive disease and/or infection(s) that can lead to sepsis. Further the sialic acid binding molecules may help reduce the pathogen burden within a subject (and thus reduce the risk of sepsis) by reducing overall pathogen carriage and/or colonization. Again, without wishing to be bound by theory, these effects may be associated with, or linked to, the sialic acid binding nature of the molecules described herein; by binding to sialic acid, the sialic acid binding molecule (for example the CBM) prevents a pathogen from exploiting (i.e. binding to or interacting with) the presence of sialic acid in certain host receptors.

As stated, the sialic acid binding molecules which are to be used in the treatment and/or prevention of sepsis or a symptom (or pathology) thereof, exhibit an ability to bind to sialic acid of the type that is commonly found on or in cell membranes and/or cell surface receptors.

Useful sialic acid binding molecules may take any form and/or belong to any class of molecule or compound (for example they may be proteins, peptides, carbohydrates, antibodies and the like) and term “sialic acid” embraces all forms of N- or O-substituted neuraminic acid and includes all synthetic, naturally occurring and/or modified forms thereof. Sialic acids may be found as components of cell surface molecules, glycoproteins and glycolipids. Most often, sialic acids are present at the end (terminal regions) of sugar chains connected to cell membranes and/or proteins. For example, some cells of the human upper respiratory tract comprise α-2,6-linked sialic acid receptors and other cells of the upper and lower respiratory tracts comprise α-2,3-linked sialic acid receptors. The sialic acid family encompasses a number (approximately 50) of derivatives that may result from acetylation, glycolylation, lactonisation and methylation at C4, C5, C7, C8 and C9. All such derivatives are to be embraced by the term “sialic acid”.

Furthermore, sialic acids are found linked α(2,3) or α(2,6) to Gal and GalNAc or α(2,8) or α(2,9) to another sialic acid. Accordingly, it is important to understand that while the term “sialic acid” is used throughout this specification, it encompasses all derivatives, analogues or variants (either naturally occurring or synthetically generated) thereof as well as monomers, dimers, trimers, oligomers, polymers or concatamers comprising the same.

Thus, a sialic acid binding molecule of this disclosure (and for use as described herein) comprises a moiety which exhibits an affinity for sialic acid—including all forms of sialic acid described above and any form of sialic acid present on the surface of a cell (perhaps as part of a cell surface receptor), for example a mammalian cell. These various forms of sialic acid may be collectively referred to as “sialic acid moieties”.

The sialic acid binding molecules of this disclosure exhibit an affinity for sialic acid and as such they may bind/couple to and/or associate with one or more sialic acid moieties. Thus, the term “sialic acid binding molecule” may further encompass any fragment of a whole sialic acid binding molecule which retains an ability to bind to or otherwise couple or associate with a sialic acid moiety.

Sialic acid binding molecules for use may comprise a single sialic acid binding molecule (a monomeric or monovalent molecule, for example) or, alternatively, two or more sialic acid binding molecules—which two or more molecules may be the same or different—a polymeric or multivalent molecule, for example.

A sialic acid binding molecule for use may comprise, consist essentially of or consist of, one or more of the sialic acid binding molecules known as “carbohydrate binding modules” (CBMs). CBMs suitable for use exhibit an affinity for sialic acid. Carbohydrate binding modules are classified into families and CBMs classed as members of the family 40 CBMs (CBM40) may be useful. The family 40 CBMs embrace molecules of approximately 200 residues and are often found at the N-terminus of GH33 sialidases. They may also be found inserted in the β-propeller of GH33 sialidases.

Exemplary carbohydrate binding modules for use may comprise the sialic acid binding domain of Vibrio cholerae NanH sialidase (VcCBM: a CBM40) and/or the equivalent (or homologous) domain from Streptococcus pneumoniae NanA sialidase (SpCBM: also a CBM40). Of course similar or homologous sialic acid binding modules present in other organisms are to be encompassed within the scope of the term “CBM”.

An exemplary Vibrio cholerae NanH sialidase amino acid sequence is deposited under accession umber A5F7A4 and is reproduced below as SEQ ID NO: 1 (781 amino acids).

MRFKNVKKTA LMLAMFGMAT SSNAALFDYN ATGDTEFDSP AKQGWMQDNT NNGSGVLTNA
DGMPAWLVQG IGGRAQWTYS LSTNQHAQAS SFGWRMTTEM KVLSGGMITN YYANGTQRVL
PIISLDSSGN LVVEFEGQTG RTVLATGTAA TEYHKFELVF LPGSNPSASF YFDGKLIRDN
IQPTASKQNM IVWGNGSSNT DGVAAYRDIK FEIQGDVIFR GPDRIPSIVA SSVTPGVVTA
FAEKRVGGGD PGALSNTNDI ITRTSRDGGI TWDTELNLTE QINVSDEFDF SDPRPIYDPS
SNTVLVSYAR WPTDAAQNGD RIKPWMPNGI FYSVYDVASG NWQAPIDVTD QVKERSFQIA
GWGGSELYRR NTSLNSQQDW QSNAKIRIVD GAANQIQVAD GSRKYVVTLS IDESGGLVAN
LNGVSAPIIL QSEHAKVHSF HDYELQYSAL NHTTTLFVDG QQITTWAGEV SQENNIQFGN
ADAQIDGRLH VQKIVLTQQG HNLVEFDAFY LAQQTPEVEK DLEKLGWTKI KTGNTMSLYG
NASVNPGPGH GITLTRQQNI SGSQNGRLIY PAIVLDRFFL NVMSIYSDDG GSNWQTGSTL
PIPFRWKSSS ILETLEPSEA DMVELQNGDL LLTARLDFNQ IVNGVNYSPR QQFLSKDGGI
TWSLLEANNA NVFSNISTGT VDASITRFEQ SDGSHFLLFT NPQGNPAGTN GRQNLGLWFS
FDEGVTWKGP IQLVNGASAY SDIYQLDSEN AIVIVETDNS NMRILRMPIT LLKQKLTLSQ
N

The CBM region of SEQ ID NO: 1 is from amino acid residue 25 to 216—this sequence may be SEQ ID NO: 2.

An exemplary Streptococcus pneumoniae NanA sialidase amino acid sequence has been deposited under accession number P62575 and is reproduced below as SEQ ID NO: 3 (1035 amino acids).

MSYFRNRDID IERNSMNRSV QERKCRYSIR KLSVGAVSMI VGAVVFGTSP VLAQEGASEQ
PLANETQLSG ESSTLTDTEK SQPSSETELS GNKQEQERKD KQEEKIPRDY YARDLENVET
VIEKEDVETN ASNGQRVDLS SELDKLKKLE NATVHMEFKP DAKAPAFYNL FSVSSATKKD
EYFTMAVYNN TATLEGRGSD GKQFYNNYND APLKVKPGQW NSVTFTVEKP TAELPKGRVR
LYVNGVLSRT SLRSGNFIKD MPDVTHVQIG ATKPANNTVW GSNLQIRNLT VYNRALTREE
VQKRSQLFKR SDLEKKLPEG AALTEKTDIF ESGRKGKPNK DGIKSYRIPA LLKTDKGTLI
AGADERRLHS SDWGDIGMVI RRSEDNGKTW GDRVTITNLR DNPKASDPSI GSPVNIDMVL
VQDPETKRIF SIYDMFPEGK GIFGMSSQKE EAYKKIDGKT YQILYREGEK GAYTIRENGT
VYTPDGKATD YRVVVDPVKP AYSDKGDLYK GNQLLGNIYF TTNKTSPFRI AKDSYLWMSY
SDDDGKTWSA PQDITPMVKA DWMKFLGVGP GTGIVLRNGP HKGRILIPVY TTNNVSHLNG
SQSSRIIYSD DHGKTWHAGE AVNDNRQVDG QKIHSSTMNN RRAQNTESTV VQLNNGDVKL
FMRGLTGDLQ VATSKDGGVT WEKDIKRYPQ VKDVYVQMSA IHTMHEGKEY IILSNAGGPK
RENGMVHLAR VEENGELTWL KHNPIQKGEF AYNSLQELGN GEYGILYEHT EKGQNAYTLS
FRKFNWDFLS KDLISPTEAK VKRTREMGKG VIGLEFDSEV LVNKAPTLQL ANGKTARFMT
QYDTKTLLFT VDSEDMGQKV TGLAEGAIES MHNLPVSVAG TKLSNGMNGS EAAVHEVPEY
TGPLGTSGEE PAPTVEKPEY TGPLGTSGEE PAPTVEKPEY TGPLGTAGEE AAPTVEKPEF
TGGVNGTEPA VHEIAEYKGS DSLVTLTTKE DYTYKAPLAQ QALPETGNKE SDLLASLGLT
AFFLGLFTLG KKREQ

The CBM region of SEQ ID NO: 3 is from amino acid residue 121 to 305—this sequence may be SEQ ID NO: 4.

Thus, CBMs for use as sialic acid binding molecules in the various aspects and embodiments of this disclosure may comprise a protein or peptide having the sequence of SEQ ID NO: 1, 2, 3 or 4 or a sequence fragment derived therefrom and which encodes a molecule with an ability to bind sialic acid (in other words a sialic acid binding molecule encoding portion of fragment of SEQ ID NOS: 1, 2, 3 or 4).

A useful sialic acid binding molecule may comprise a proteinaceous moiety encoded by the sialic acid binding domain of the nanH gene (encoding sialidase) of V. cholerae (as provided by SEQ ID NO: 1) or an equivalent or homologous gene present in another organism (for example the equivalent/homologous nanA sialidase gene of S. pneumoniae: see SEQ ID NO: 3).

A sialic acid binding molecule for use may comprise from about residue 1, 5, 10, 15, 25 or 30 (i.e. from 1-30 or from any amino acid residue there between) to about residue 150, 175, 200, 210, 216, 220-781 (to any residue from 150 to 781 including any residue therebetween) of the V. cholerae sialidase molecule of SEQ ID NOS: 1 and 2. For example a sialic acid binding molecule for use may comprise a peptide having a sequence corresponding to residue 25 to about residue 216 of SEQ ID NO: 1 above.

A further suitable sialic acid binding molecule may comprise a protein or peptide having the sequence of SEQ ID NO: 3 or 4 or a sialic acid binding fragment thereof. For example, a useful sialic acid binding molecule may comprise a proteinaceous moiety encoded by the sialic acid binding domain of the Streptococcus pneumoniae nanA gene (encoding sialidase). For example a sialic acid binding molecule for use may comprise from about residue 80, 90, 100, 110, 120, 121 to 130 (i.e. from any of about residues 80 to 130 including any residue therebetween) to about residue 250, 275, 300, 305, 310, 320-1035 (i.e. to any residue from about 250-1035 including to about any residue therebetween) of the S. pneumoniae sialidase molecule of SEQ ID NOS: 3 and 4. For example, a sialic acid binding molecule for use may comprise a peptide having a sequence corresponding to residue 121 to about residue 305 of SEQ ID NO: 3 above.

A sialic acid binding molecule for use may comprise one or more CBMs. For example, suitable sialic acid binding molecules may comprise single CBMs—for example a single VcCBM or a single SpCBM. Alternatively, a sialic acid binding molecule for use may comprise a plurality or multiple (i.e. two or more) CBMs. Sialic acid binding molecules which comprise a plurality of CBMs may be termed “multivalent sialic acid binding molecules” or “multivalent CBMs”. A multivalent CBM may, for example, comprise two or more (for example three, four, five or six) VcCBMs or two or more SpCBMs. A multivalent CBM may comprise a mixture of different CBMs, for example one or more VcCBMs with one or more SpCBMs.

Thus, the various aspects and embodiments of this disclosure (uses, sialic acid binding molecules for use, methods and medicaments) may exploit sialic acid binding molecules which comprise, consist of or consist essentially of sialic acid binding molecules selected from the group consisting of:

(i) one or more VcCBM(s);

(ii) one or more SpCBM(s); and

(iii) a multivalent CBM.

As such, the present disclosure provides Vc4CBM for use in the treatment and/or prevention of sepsis and/or one or more symptoms thereof.

Further provided is the use of Vc4CBM in the manufacture of a medicament for use in the treatment and/or prevention of sepsis and/or one or more symptoms thereof.

The disclosure also relates to a method of treating or preventing sepsis and/or one or more symptoms thereof, said method comprising the steps of administering to a subject in need thereof, a therapeutically effective amount of Vc4CBM.

For the avoidance of doubt, Vc4CBM comprises, consists essentially of or consists of four Vibrio cholerae NanH sialidase CBM units linked, bound or conjugated together. Vc4CBM may be described as a tandem-repeat multivalent protein based on the Family 40 sialic acid binding domain (CBM) of the nanH gene encoding the sialidase from V. cholerae. Molecules of this type may be generated using PCR-based cloning techniques and a suitable method for the generation of multivalent molecules of this type is described in, for example, Connaris et al, 2009 (Enhancing the Receptor Affinity of the Sialic Acid-Binding Domain of Vibrio cholerae Sialidase through multivalency; J. Biol. Chem; Vol. 284(11); pp 7339-7351). For example, multivalent CBM molecules, including the likes of Vc4CBM may be prepared as constructs comprising multiple CBMs linked by amino acid/peptide linkers. Each CBM (for example VcCBM) may be linked to another by, for example, peptides comprising 5, 10 or 15 amino acids. By way of example any one or more of the following peptides may be used to link two or more CBMs to produce a multivalent CBM:

(1) 5 amino acid linkers:
ALNGS
LQALG
GGNSG
(ii) 10 amino acid linkers:
ALNGSGGGSG
LQALGGGGSL
(iii) 15 amino acid linkers:
ALNGSGGGSGGGGSG

As shown in FIG. 8, a Vc4CBM molecule may conform to General Formula 1, wherein Peptide Linkers A, B and/or C are selected from the linker options presented above as (i), (ii) and/or (iii). It should be noted that the term “VcCBM40” embraces not only the complete family 40 CBM derived from Vibrio cholerae (NanH sialidase) but also sialic acid binding fragments derived therefrom. Indeed, each of the VcCBM units shown in General Formula 1 may be selected from the group consisting of:

(i) a Vibrio cholerae NanH sialidase CBM; and

(ii) a Vibrio cholerae NanH sialidase CBM sialic acid binding fragment thereof.

Thus, each of the VcCBM units of the molecule shown in General Formula 1 may be the same or different.

The sialic acid binding molecules for use may further comprise an oligomerisation domain. Suitable oligomerisation domains may exhibit an ability to self-associate to form multimer structures, for example trimers. An oligomerisation domain for use may comprise any molecule with the above mentioned oligomerisation properties or any functional fragment thereof. For example, one or more (for example two) sialic acid binding molecules (for example CBMs) may be bound, coupled or fused to an oligomerisation domain—the resulting sialic acid binding molecule::oligomerisation domain “fusion” may then be used (with one or more other such “fusions”) as a molecule for modulating cell growth and/or activity and/or for treating or preventing any of the diseases and/or conditions disclosed herein.

Suitable oligomerisation domains may be derived from, for example, Pseudomonas aeruginosa pseudaminidase. An exemplary Pseudomonas aeruginosa pseudaminidase sequence amino acid sequence has been deposited under accession number PAO579 and is reproduced below as SEQ ID NO: 5 (438 amino acids).

MNTYFDIPHR LVGKALYESY YDHFGQMDIL SDGSLYLIYR RATEHVGGSD GRVVESKLEG
GIWSAPTIVA QAGGQDFRDV AGGTMPSGRI VAASTVYETG EVKVYVSDDS GVTWVHKFTL
ARGGADYNFA HGKSFQVGAR YVIPLYAATG VNYELKWLES SDGGETWGEG STIYSGNTPY
NETSYLPVGD GVILAVARVG SGAGGALRQF ISLDDGGTWT DQGNVTAQNG DSTDILVAPS
LSYIYSEGGT PHVVLLYTNR TTHFCYYRTI LLAKAVAGSS GWTERVPVYS APAASGYTSQ
VVLGGRRILG NLFRETSSTT SGAYQFEVYL GGVPDFESDW FSVSSNSLYT LSHGLQRSPR
RVVVEFARSS SPSTWNIVMP SYFNDGGHKG SGAQVEVGSL NIRLGTGAAV WGTGYFGGID
NSATTRFATG YYRVRAWI

The oligomerisation domain of SEQ ID NO: 5 is from amino acid residue 333 to 438—this sequence may be SEQ ID NO: 6.

Thus an oligomerisation domain for use may comprise from about residue 250, 275, 300, 310, 320, 333, 340 to 350 (i.e. from about residue 250 to about residue 350 including from about any residue therebetween) to about residue 400, 410, 420, 430 or 438 (i.e. to about any residue from about residue 400 residue 438 including to about any residue therebetween) of the P. aeruginosa pseudaminidase trimerisation domain (PaTD) provided by SEQ ID NO: 5. For example, a useful sialic acid binding molecule may exploit an oligomerisation domain comprising residues 333 to 438 of SEQ ID NO: 6.

A sialic acid binding molecule for use may comprise one or more of the CBM based molecules presented in FIG. 1. For example, a suitable sialic acid binding molecule may comprise (consist essentially of, or consist of) two or more VcCBMs optionally fused, bound or conjugated to an oligomerisation domain (such as a PaTD or oligomerisation fragment thereof). The sialic acid binding molecule may comprise, consist or consist essentially of two fused (or bound) VcCBMs which are in turn fused to an oligomerisation domain (see, for example, molecule Vc2CBMTD shown in FIG. 1).

Other sialic acid binding domains for use may comprise two or more SpCBMs optionally fused, bound or conjugated to an oligomerisation domain (such as a PaTD or an oligomerisation fragment thereof). Sialic acid binding molecules for use may comprise, consist or consist essentially of two fused (or bound) SpCBMs which are in turn fused to an oligomerisation domain (see, for example, molecule Sp2CBMTD shown in FIG. 1).

Given that sepsis is characterised by an exacerbated host immune response, the sialic acid binding molecules of this disclosure (including, for example, Vc4CBM) may find application in compositions, medicaments and methods for modulating sepsis associated immune responses. A sepsis associated immune response may be an immune response that, when compared to a normal immune response (e.g. one that is not a sepsis associated immune response) is exacerbated, exaggerated and/or inappropriate. As stated, the sepsis associate immune response may lead to host tissue damage and/or organ damage/failure and may comprise the dysregulation of innate immune responses as well as the production and/or over/under production of certain cytokines and/or pro-coagulation cytokines (including, for example, tumor necrosis factor, interleukin 1 and interleukin 6). Again, any dysregulation and/or cytokine over/under production may be measured, quantified and/or determined relative to the level of cytokine under/over-production and/or regulation in an uninfected host.

Thus, the disclosure provides a sialic acid binding molecule for use in modulating (for example dampening, inhibiting and/or ablating) a sepsis associated immune response. The disclosure may further relate to a method of modulating a sepsis associated immune response, said method comprising administering a subject in need thereof (the subject being a subject (i) suffering from sepsis and/or with a sepsis associated immune response or (ii) predisposed or susceptible thereto). The disclosure also provides the use of a sialic acid binding molecule in the manufacture of a medicament for modulating a sepsis associated immune response.

It should be noted that the various uses and methods described herein may comprise the administration of a non-cell cross-linking, non-cell or red/white cell agglutinating, non-blood clotting cascade/symptom and/or non-stroke/thrombosis symptom inducing or activating amount of a sialic acid binding molecule.

Sialic acid binding molecule based treatments, compositions, methods and medicaments (all of which are described herein—in particular those based on Vc4CBM) represent an advantage over prior art equivalents as the sialic acid binding molecules may not induce, cause or accelerate the release of microbial pro-inflammatory components which can exacerbate or induce sepsis and lead to severe sepsis and shock. Further, in contrast to antimicrobial peptides (AMPs), the sialic acid binding molecules are less toxic and less likely to be rendered useless through the development of resistance.

Further, it should be noted that the various uses, methods and medicaments described herein may exploit one or more of the sialic acid binding molecules described herein. For example, two or more different sialic acid binding molecules may be administered to a subject together, concurrently or separately.

The present disclosure may provide compositions for use in the various uses, medicaments and methods described herein. As such, any of the sialic acid binding molecule(s) described herein may be formulated for use. For example, a sialic acid binding molecule (or molecules) may be formulated as therapeutic or pharmaceutical compositions. The various compositions may comprise one or more of the sialic acid binding molecules described herein and any given treatment may require the administration (together, concurrently or separately) of one or more of these compositions.

The various sialic acid binding molecules described herein may be formulated for enteral (including oral), parenteral and/or topical administration and one of skill will appreciate that the precise formulation may vary depending on the route of administration. Pharmaceutical compositions according to the present invention may be prepared conventionally, comprising substances that are customarily used in pharmaceuticals and as described in, for example, Remington's The Sciences and Practice of Pharmacy, 22nd Edition (Pharmaceutical Press 2012) and/or Handbook of Pharmaceutical Excipients, 7th edition (compiled by Rowe et al, Pharmaceutical Press, 2012)—the entire content of all of these documents and references being incorporated by reference.

A therapeutic or pharmaceutical composition of this disclosure (that is a composition comprising a sialic acid binding molecule and for use in any of the medicaments or methods described herein—including the methods of or medicaments for, treating or preventing sepsis) may be formulated together with one or more pharmaceutically acceptable excipients, carriers, adjuvants and buffers. The compositions can be administered, e.g. orally (including mucosally), parentally, enterally, intramuscularly, subcutaneously, intravenously or via any other routes useful to achieve the desired effect (in this case effects which include, modulation of cell growth/activity, treatment or prevention of diseases/conditions associated with the same and/or cancer and/or modulation of tumour growth). As stated, depending on the chosen route of administration, the exact composition of the formulation may vary.

A therapeutic or pharmaceutical formulation comprising a sialic acid binding molecule and for administration to a subject may be coated, encapsulated or enveloped in a material which protects the sialic acid binding molecule from the action of enzymes, acids and other natural compounds/conditions (including, for example, compounds (including antibodies), cells and processes of the immune system) which may inactivate or denature the compound and/or its sialic acid binding properties.

Among the various standard and conventional excipients that may be available for use in compositions comprising sialic acid binding molecules, are those pharmaceutically acceptable organic or inorganic carrier substances which are suitable for parenteral, enteral, oral (including mucosal) and other routes of administration that do not deleteriously react with the sialic acid binding molecule(s).

Where the sialic acid binding molecules are to be formulated for parental administration, the compositions may be sterile.

The composition may comprise an oil-based or aqueous solution, a suspension and/or an emulsion.

In other embodiments, the composition may take the form of an implant, such as for example a (dissolvable or biodegradable) film, pessary or implant (including suppositories).

The pharmaceutical preparations comprising sialic acid binding molecules may be mixed with stabilizers, wetting agents, emulsifiers, salts (for use in influencing osmotic pressure), buffers and/or other substances that do not react deleteriously with the active compounds.

One or more of the sialic acid binding molecules described herein may be formulated for and administered, orally. As stated, oral administration would include mucosal administration which would itself would include administration intranasally and/or by inhalation.

Compositions for use may include solid dosage forms which are suitable for oral administration. These may include, for example, capsules, tablets, pills, powders, and granules. In any given solid dosage form, the sialic acid binding molecule may be admixed with at least one inert pharmaceutically-acceptable excipient. Examples of suitable excipients will be known to one of skill in this field but may include, for example, fillers or extenders, humectants, wetting agents, binders, disintegrating agents, solution retarders, absorption accelerators, adsorbents, lubricants or mixtures thereof. A tablet, pill or capsule may further comprise a buffering agent. Solid dosage forms such as tablets, dragees, capsules, pills and/or granules also can be prepared with coatings and shells, such as coatings which protect against the gastrointestinal environment and/or stomach acid.

A solid dosage form may contain opacifying agents, and can also be formulated so as to ensure the delayed release of the active agent (in this case the sialic acid binding molecule) in or to a specific part of the intestinal tract.

Solid compositions for oral administration can be formulated in a unit dosage form, each dosage containing an appropriate dose of the sialic acid binding molecule. The exact amount of sialic acid binding molecule contained within any given solid dosage form will vary depending on the intended use. A solid composition may contain a “unit dose”—a unit dose containing a quantity of sialic acid binding molecule calculated to produce the desired effect (for example modulation of cell growth and/or activity) over the course of a treatment period. Liquid dosage forms for oral administration may (as stated) include emulsions, solutions, suspensions, syrups, and elixirs. In addition to the compound or composition, the liquid dosage forms may contain inert diluents commonly used in the art, such as water or other solvents, solubilizing agents and emulsifiers.

Any suitable amount of a sialic acid binding molecule (for example any of the CBM type molecules described herein) may be used. For example, whether a composition comprising a sialic acid binding molecule (for example a CBM such as Vc4CBM or Vc2CBMTD) is to be administered intravenously or mucosally (for example intranasally) the dose of sialic acid binding molecule may comprise anywhere between about 1 μg and about 1000 μg. For example a dose of about (for example +/−0.5 μg) 10 μg, 11 μg, 12 μg, 13 μg, 14 μg, 15 μg, 20 μg, 30 μg, 40 μg, 50 μg, 100 μg, 200 μg, 300 μg, 400 μg, 500 μg, 600 μg, 700 μg, 800 μg, 900 μg or 950 μg of the sialic acid binding molecule may be used. These amounts may be provided in any suitable volume of excipient, diluent or buffer. For example the amount of sialic acid binding molecule may be provided in anywhere between about 1 μl to about 5 ml of excipient, diluent or buffer. For example, the required amount of sialic acid binding molecule may be combined (or formulated) with about 5 μl, 10 μl, 15 μl, 20 μl, 25 μl, 30 μl, 35 μl, 40 μl, 45 μl, 50 μl, 55 μl, 60 μl, 65 μl, 70 μl, 75 μl, 80 μl, 85 μl, 90 μl, 95 μl, 100 μl, 200 μl, 300 μl, 400 μl, 500 μl, 600 μl, 700 μl, 800 μl, 900 μl, 1 ml, 2 ml, 3 ml or 4 ml. For example, for intranasal administration and amount of sialic acid binding molecule (for example about 100 μg or 500 μg) may be formulated in about 50 μl excipient for use as a single dose. Further and for intravenous use, small amounts of sialic acid binding molecule may be used. For example amounts of about 10 μg, 11 μg or 12.5 μg, 13 μg, 14 μg or 15 μg may be used intravenously.

DETAILED DESCRIPTION

The present invention will now be described in detail with reference to the following figures which show:

FIG. 1: Building blocks of the multivalent CBM forms and their affinities for sialic acid. a, VcCBM, residues 25-216 of the V. cholerae sialidase (PDB:1w0p) with α-2,3-sialyllactose drawn as spheres. b, SpCBM, residues 121-305 of S. pneumoniae NanA sialidase with α-2,3-sialyllactose (PDB:4c1w). c, TD, the trimerisation domain, residues 333-438, of the P. aeruginosa pseudaminidase (PDB:2w38) in rainbow colours; the other two monomers in single colors. d, Multivalent forms: their molecular weights, valencies and binding affinities for α2,3-sialyllactose as determined by surface plasmon resonance (SPR) at 25° C. (K_D values for VcCBM, Vc2CBM and Vc3CBM had been reported previously⁷). Tandem repeat CBMs, and oligomeric CBMs fused to TD are linked by a 5-amino linker (details in Full Methods).

FIG. 2: Survival time of mice infected intravenously only with 8.5×10⁵ CFU/mouse (control) or with same number of pneumococci plus 12.5 μg/mouse Vc4CBM. The protein was administered with bacterial inoculums and mice were observed for 168 h. The survival time of each animal is shown with a dot. The median survival time is given with a horizontal line and was 59 h (SD: 53) for control and 84 h (SD:55) for Vc4CBM group.

FIG. 3: Survival time of mice infected intravenously only with approximately 6.3-7.5×10⁵ CFU/mouse (control) or with same number of pneumococci plus 13-15 μg/mouse Vc4CBM. The protein was administered with bacterial inoculums and mice were observed for 168 h. The survival time of each animal is shown with a dot. The median survival time is given with a horizontal line and was 59 h (SD: 48.7) for control and 168 h (SD:48.5) for Vc4CBM-treated group.

FIG. 4: The effect of intranasal administration of two mCBM40s on survival of Streptococcus pneumoniae D39-infected mice. CD1 outbred mice (n=20) were administered intranasally with either a single dose of 500 μg Vc4CBM (CBM1) or 100 μg Vc2CBMTD (CBM2) a day before (A), at the time of (B) or 1 day after intranasal infection (C) with S. pneumoniae D39. Control group received PBS only. Difference in percent median survival was calculated using Wilcoxon test. *p<0.05, ***p<0.001 relative to the control that received PBS.

FIG. 5: The impact of mCBM40s on disease sign scores in pneumococcal infection. CD1 mice that received either 500 μg Vc4CBM (CBM1) or 100 μg Vc2CBMTD (CBM2) a day before (−1), at the time of (0) or 1 day after (+1) intranasal infection when administered with a lethal dose of S. pneumoniae D39, were monitored for signs of disease at 24, 36 and 48 h post infection. A score of 2, 4, or 6 was given if the animals were piloerect, hunched, or lethargic, respectively. Each column represents the mean disease sign scores at different time points for 8 to 14 animals that eventually died. The vertical lines are for standard error of mean. Data was analysed by two-way ANOVA followed by Dunnett's multiple comparisons test. *p<0.05, ***p<0.001

FIG. 6: The effect of mCBM40s on mortality time of Streptococcus pneumoniae infected mice after intranasal administration. CD1 mice were administered intranasally with either 500 Vc4CBM (CBM1) or 100 μg Vc2CBMTD (CBM2) a day before (−1), at the time of (0) or 1 day after intranasal infection (+1) with S. pneumoniae D39. Difference in time to mortality was calculated using Mann-Whitney U test. *p<0.05, ****p<0.0001 relative to the control that received PBS.

FIG. 7: The impact of CBM protein on pneumococcal bacteremia: CD1 mice received either 500 μg Vc4CBM (CBM1) or 100 μg Vc2CBMTD (CBM2) a day before (−1), at the time of (0) or 1 day after (+1) intranasal infection with lethal dose of S. pneumoniae D39. A blood sample was taken from the tail vein 24 h post infection and CFU/ml was determined by serial dilution and plating. Each column represents the mean CFU/ml for 8 to 14 animals. Vertical lines are for standard error of mean. Data was analysed by two-way ANOVA followed by Dunnett's multiple comparisons test. *p<0.05 relative.

FIG. 8: A schematic referred to hereinafter as General Formula 1. An exemplary Vc4CBM may take the form of General Formula 1.

EXAMPLE 1

When identifying different routes of mCBM40 delivery in vivo, it was noted that a tetrameric Vc-based CBM40 (Vc4CBM), protected mice when given intravenously with a lethal dose of Streptococcus pneumoniae. This suggests a role for CBMs (including multivalent molecules comprising the same) in the treatment and/or prevention of sepsis, its symptoms and/or associated pathologies.

Multivalent forms of CBM40s target sialylated cell surfaces and therefore it was expected that, at certain concentrations, agglutination of red (and white) blood cells in vivo would occur as a result of cross-linking protein-ligand interactions between cells. This could potentially lead to a number of blood clotting symptoms such as thrombosis or stroke.

The results of initial dose-response intravenous Vc4CBM dosing in mice and clinical activity show that an intravenous Vc4CBM dose of 12.5 μg/mouse was tolerated.

Production of the Vc4CBM in E. coli meant that it was necessary to eliminate contamination of the CBM preparation with endotoxin as the cause of any observed adverse events—this would ensure that the results represented a proper assessment of the effect the Vc4CBM molecule against sepsis. As stated an intravenous dose of 12.5 μg Vc4CBM was tolerated by mice and a pneumococcal challenge was attempted.

Groups of mice (n=5) were infected intravenously with a lethal dose of pneumococcus (8.5×10⁵ CFU/mouse) in the presence or absence of a single dose of Vc4CBM (12.5 μg/mouse). Survival times of mice are shown in FIG. 2. There appeared to be a slight, increase in survival of mice in the CBM-treated group (median survival time ˜84 h) compared to the control group (59 h). To determine whether the survival rate in mice could be improved, a further study was performed whereby the pneumococcal CFU dose was slightly reduced to correspond with a slight increase in the amount of Vc4CBM given intravenously. The results of this experiment are shown in FIG. 3. Here it appears that the survival rate of mice improved significantly under the conditions tested, with a combined survival rate of 70% after 7 days in the CBM-treated groups, displaying a median survival time of 168 h, compared to 20% survival of mice in the untreated, infected groups (median survival time of 59 h).

These results indicate that mCBM40s have the potential to alleviate symptoms of sepsis in a bacterially-infected host. In the case of Vc4CBM, it is likely that this biologic modulates the immune response by dampening down the pro-inflammatory cascade of a S. pneumoniae infection that leads to sepsis. Further, while there was a concern that the multivalent CBMs might (through the cross-linking of protein-ligand interactions between cells) induce agglutination of cells (including red (and white) blood cells) in vivo (which could potentially lead to the induction of blood clotting cascades and a number of blood clotting symptoms such as thrombosis or stroke), this did not occur.

EXAMPLE 2

Novel, bacterially-derived, proteins (mCBM40s) that target and bind host cell surface sialic acid-receptors with high affinity (JBC (2009), 284, 7339) have been engineered. When mCBM40s are administered in mice, they are shown to be non-toxic and can protect mice from respiratory pathogens (PNAS (2014) 111, 6401; AAC 59(3): 1495-1504). Using a pneumococcal-challenged mouse model, it has been shown that mCBM40, Vc4CBM can provide significant survival rates in mice against a lethal pneumococcal infection. To further evaluate the protective utility of mCBM40 proteins in reducing bacteraemia in a pneumococcal mouse model, mCBM40s were also given intranasally (as described below).

mCBM40 Dosing Via the Intranasal Route

Method: All CBM40 proteins (Vc4CBM and Vc2CBMTD, endotoxin-free) were prepared as described in Connaris et al (2014)¹⁰. Groups of female mice (CD1 outbred strain, n=10 to 20), weighing 28-35 g, were intranasally administered with a single dose of either Vc4CBM (up to 500 μg) or Vc2CBMTD (up to 100 μg) in 50 μl sterile PBS, either one day before (D−1), on the day (D0) or one day after (D+1) a lethal intranasal challenge with approximately 1×10⁶ CFU of S. pneumoniae D39 (in 50 μl of PBS)/mouse. The control group received PBS only. Clinical signs of disease were monitored and recorded over 7 days (168 h), where an ascending score from 0 to 6 (0 being no clinical symptoms) was given to all animals. At the end of experiment, the lungs, and blood will be collected and bacterial counts determined. Bacteraemia was monitored by sampling blood at specific time-points during infection, with the number of colony forming units from blood determined using the technique as described by Miles and Misra¹¹.

TABLE 1
The impact of mCBM40 dosing on survival of CD1 mice
challenged with a lethal pneumococcal dose.
*Survival of treated groups was evaluated after 168 h.
	Treatments	Dead	Survived	% Survival*
	CBM1/−1	8	12	60
	CBM1/0	12	8	40
	CBM1/+1	11	9	45
	CBM2/−1	9	11	55
	CBM2/0	14	6	30
	CBM2/+1	8	12	60
	Control (PBS)	14	6	30

SUMMARY

1. mCBM40s demonstrated reduction of bacteraemia in mice when intranasally given in a lethal pneumococcal infection model.

REFERENCES

• 1. “The Third International Consensus Definitions for Sepsis and Septic Shock (Sepsis-3)”. Feb. 23, 2016. doi:10.1001/jama.2016.0287.
• 2. Jawad, I; Lukšić, I; Rafnsson, S B (2012). Assessing available information on the burden of sepsis: Global estimates of incidence, prevalence and mortality. Journal of Global Health 2 (1): 010404.
• 3. Hoffman, S J; Outterson, K; Røttingen, J A; Cars, O; Clift, C; Rizvi, Z; Rotberg, F; Tomson, G; Zorzet, A (2015). An international legal framework to address antimicrobial resistance. Bulletin of the World Health Organization 93 (2): 66.
• 4. Bahar, A A; Ren, D (2013) Antimicrobial Peptides. Pharmaceutical (Basel) 6 (12): 1543-1575.
• 5. Yeaman, M R; Yount, N Y (2003) Mechanisms of antimicrobial peptide action and resistance. Pharmacol. Rev. 55:27-55
• 6. Fox, J L (2013). Antimicrobial peptides stage a comeback. Nature Biotechnology 31: 379-382
• 7. Connaris, H; Crocker, P R; Taylor, G L (2009). Enhancing the receptor affinity of the sialic acid-binding domain of Vibrio cholerae sialidase through multivalency. J. Biol. Chem. 284(11): 7339-51
• 8. Connaris, H; Govorkova, E A; Ligertwood, Y; Dutia, B M; Yang, L; Tauber, S; Taylor, M A; Alias, N; Haga, R; Nash, A A; Webster R G; Taylor G L (2014). Prevention of influenza by targeting host-receptors using engineered proteins. PNAS 111(17): 6401-6406.
• 9. Govorokova, E A; Baranovich, T; Marathe, B M; Yang, L; Taylor, M A; Webster, R G; Taylor, G L; Connaris, H (2015). Sialic acid-binding protein Sp2CBMTD protects mice against lethal challenge with emerging influenza A (H7N9) virus. AAC 59(3): 1495-1504.
• 10. Connaris H, Govorkova E A, Ligertwood Y, Dutia B M, Yang L, Tauber S, Taylor M A, Alias N, Hagan R, Nash A A, Webster R G, Taylor G L. 2014. Prevention of influenza by targeting host receptors using engineered proteins. Proc Natl Acad Sci USA 111:6401-6406.
• 11. Miles, A A; Misra, S S; Irwin, J O (November 1938). “The estimation of the bactericidal power of the blood.”. The Journal of Hygiene. 38 (6): 732-49.

Claims

1. A method of treating and/or preventing sepsis and/or one or more symptoms thereof, said method comprising administering a sialic acid binding molecule to a subject who has sepsis or an infection which could lead to sepsis or a subject diagnosed as suffering from one or more sepsis associated pathologies, wherein the sialic acid binding molecule comprises two or more family 40 carbohydrate binding molecules.

2. The method of claim 1, wherein the sialic acid binding molecule comprises the sialic acid binding domain of Vibrio cholerae NanH sialidase and/or the sialic acid binding domain of Streptococcus pneumoniae NanA sialidase.

3. The method claim 2, wherein the Vibrio cholerae NanH sialidase comprises the amino acid sequence of SEQ ID NO: 1 or 2.

4. The method of claim 2, wherein the Streptococcus pneumoniae NanA sialidase comprises the amino acid sequence of SEQ ID NO: 4.

5. The method of claim 1, wherein the sialic acid binding molecule comprises (i) four Vibrio cholerae NanH sialidase CBM units linked, bound, or conjugated together (Vc4CBM); and/or (ii) two Vibrio cholerae NanH sialidase CBM units fused, bound, or conjugated to a Pseudomonas aeruginosa pseudaminidase trimerisation domain (Vc2CBMTD).

6. The method of claim 1, wherein the sialic acid binding molecule is formulated for oral, mucosal or parenteral administration.

7. The method of claim 1, wherein the sialic acid binding molecule is formulated for intranasal administration.

8. The method of claim 1, wherein the sialic acid binding molecule is formulated for intravenous administration.