life-8k_20180125.htm

 

 

UNITED STATES

SECURITIES AND EXCHANGE COMMISSION

Washington, D.C. 20549

 

 

FORM 8-K

 

 

CURRENT REPORT

Pursuant to Section 13 or 15(d)

of the Securities Exchange Act of 1934

January 25, 2018

Date of Report (Date of earliest event reported)

 

ATYR PHARMA, INC.

(Exact name of registrant as specified in its charter)

 

 

 

 

 

 

 

Delaware

 

001-37378

 

20-3435077

(State or other jurisdiction

of incorporation)

 

(Commission

File Number)

 

(IRS Employer

Identification No.)

 

3545 John Hopkins Court, Suite #250

San Diego, California 92121

 

(Address of principal executive offices, including zip code)

 

(858) 731-8389

 (Registrant’s telephone number, including area code)

 

Check the appropriate box below if the Form 8-K filing is intended to simultaneously satisfy the filing obligations of the registrant under any of the following provisions:

 

Written communications pursuant to Rule 425 under the Securities Act (17 CFR 230.425)

 

Soliciting material pursuant to Rule 14a-12 under the Exchange Act (17 CFR 240.14a-12)

 

Pre-commencement communications pursuant to Rule 14d-2(b) under the Exchange Act (17 CFR 240.14d-2(b))

 

Pre-commencement communications pursuant to Rule 13e-4(c) under the Exchange Act (17 CFR 240.13e-4(c))

 

Indicate by check mark whether the registrant is an emerging growth company as defined in Rule 405 of the Securities Act of 1933 or Rule 12b-2 of the Securities Exchange Act of 1934.

Emerging growth company    

If an emerging growth company, indicate by check mark if the registrant has elected not to use the extended transition period for complying with any new or revised financial accounting standards provided pursuant to Section 13(a) of the Exchange Act.    

 


 

Item 7.01                                           Regulation FD Disclosure.

aTyr Pharma, Inc. (the “Company”) is participating at the ASCO-SITC Clinical Immuno-Oncology Symposium held January 25-27 in San Francisco, California.  On January 25, 2018, the Company presented a poster presentation titled, “Identification of Novel Liquid Biopsy for Monitoring the Immune Set Point in Both Solid Tumor and Hematological Malignancy Patients.”  The poster presentation has been posted on the Company’s website and is attached hereto as Exhibit 99.1.

 

The information under this Item 7.01, including Exhibit 99.1 hereto is being furnished herewith and shall not be deemed “filed” for the purposes of Section 18 of the Securities Exchange Act of 1934, as amended (the “Exchange Act”), or otherwise subject to the liabilities of that section, nor shall such information be deemed incorporated by reference into any filing under the Securities Act of 1933, as amended, or the Exchange Act, except as expressly set forth by specific reference in such filing.

 

 

2


 

Item 9.01                                           Exhibits.

 

(d) Exhibits.

 

99.1

 

Poster presentation titled “Identification of Novel Liquid Biopsy for Monitoring the Immune Set Point in Both Solid Tumor and Hematological Malignancy Patients.”

 

 

3


 

SIGNATURE

 

Pursuant to the requirements of the Securities Exchange Act of 1934, the registrant has duly caused this report to be signed on its behalf by the undersigned hereunto duly authorized.

 

 

ATYR PHARMA, INC.

 

 

 

 

 

 

 

By:

/s/ John T. Blake

 

 

John T. Blake

 

 

Senior Vice President, Finance

 

 

 

Date: January 25, 2018

 

 

 

 

4

life-ex991_69.htm

Exhibit 99.1

Identification of Novel Liquid Biopsy Biomarker for Monitoring the Immune Set Point in Both Solid Tumor and Hematological Malignancy Patients

Ryan Adams, Elisabeth Mertsching, Leslie Nangle, Kathy Ogilvie, Andrea Cubitt, David J King, John Mendlein

aTyr Pharma, San Diego, CA

 

 

 

Introduction A number of non-canonical functions of proteins generated from tRNA synthetase genes have been reported, demonstrating diverse roles for these proteins outside of protein synthesis. These include roles in regulating inflammatory responses, angiogenesis and mTOR signaling (Wakasugi & Schimmel, 1999; Park et al., 2008, Arif et al., 2017). • The gene for histidyl-tRNA synthetase (HARS) gives rise to a number of splice variants, many of which have lost their catalytic activity, but which retain the N-terminal domain of 59 amino acids, sometimes referred to as the WHEP domain (Xu et al., 2012, Lo et al., 2014). This domain was appended to HARS during evolution of multicellular organisms and is not essential for protein synthetic activity (as in prokaryotic organisms) but is retained with high homology across mammalian species. • Proteins derived from the HARS gene, both full-length and splice variants, are present in human circulation and play a role in modulating immune responses. We have termed the extracellular HARS proteins as Resokine proteins, to differentiate them from the intracellular enzyme involved in protein synthesis. Resokine proteins, all of which contain the N-terminal HARS domain (the immunomodulatory domain, or iMod domain), have activity to modulate T cell activity and levels of iMod domain proteins are elevated in cancer, both in human plasma and in syngeneic tumor models in mice. In addition, monoclonal antibodies to the iMod domain are capable of inhibiting tumor growth in mice. Resokine Proteins: Extracellular Histidyl-tRNA Synthetase Gene Products With Immune Modulation Activity Intracellular (Protein Synthesis Function) Histidyl-tRNA Synthetase 509 AA Function: Protein synthesis iMod Domain Aminoacylation Domain Anticodon- Binding Domain Resokine N-terminal iMod domain Full length HARS: 509 AA iMod domain (SV9): 59 AA Function: Immunomodulation Function: Immunomodulation Resokine secretion Extracellular (Naturally Occurring In Circulation) iMod Domain Structural Similarity to Cytokines Resokine iMod domain 4α helical cytokine Examples include IL-2 IL-4 IL-6 IL-10 IL-13 IL-23 Interferon Type 1/2 Resokine (the extracellular proteins derived from the HARS gene) is secreted from cells and circulates naturally in all individuals tested. The N-terminal “iMod” domain has structural similarity to 4 alpha– helical bundle cytokines. Overlay shown is with human IL-6, but structure is similarly conserved among other members of the family. • The N-terminal iMod domain is conserved among all the characterized splice variants arising from the HARS gene, and thus constitutes a potential epitope that can be targeted by antibodies to neutralize all forms of Resokine. iMod Domain: Universal Epitopes Across the Resokine Family Splice Variant (SV) Resokine HARS: Splice Variants & Fragments iMod Domain Splice Variants

 


 

Resokine Is a Novel Immunomodulator To test in vitro effects of Resokine on T cell activation, recombinant Resokine was purified and verified to be > 95% pure with low/undetectable endotoxin contamination. Resokine was then tested by addition to T cells undergoing activation in vitro with antibodies to CD3/CD28. Resokine Reduces Cytokine and Granzyme B Release During T Cell Activation Human T Cell IL-2 Release 24h Stimulation (anti-CD3/CD28) 1500 IL-2 (pg/mL) 1000 500 0 Vehicle 10 30 100 300 1000 3000 10,000 Unstim Vehicle 10 30,000 Granzyme B (pg/mL) LLOD Human T Cell Granzyme B Release 24h Stimulation (anti-CD3/CD28) Stimulated Resokine (pM) Similar for: INFγ, TNF, TGFβ, IL-13, IL-4… ****p < 0.0001; ***p < 0.001; **p < 0.01 ****p < 0.0001 Resokine Inhibits Up-regulation of CD40L and Other Cell Surface Activation Markers 24h Stimulation (anti-CD3/CD28) Anti-CD3/CD28 (24 h) Anti-CD3/CD28 (24h) Stimulation + Vehicle Stimulation + Resokine (100pM) CD4+ CD154L+ 47.2 CD4+ CD154L+ 12.0 CD4+ T cell count 150 100 50 0 10-1 100 101 102 103 CD40L Similar for: CD69, 4-1BB, PD-1, ICOS… Human T cells were isolated from fresh human blood via PBMC by standard techniques. T cells were activated by antibodies to CD3 (plate bound) and CD28 (soluble) using sub-optimal stimulation conditions in the presence of Resokine or buffer vehicle. After 24 hours, supernatant was collected for the measurement of cytokines or granzyme B by ELISA, and cell surface markers were analyzed by flow cytometry. Data shown for CD4 positive T cells. Resokine Inhibits Up-regulation of PD-1 and CTLA-4 PD-1 CTLA4 Vehicle Resokine % Positive Unstimulated Stimulated 30 20 10 0 6 4 2 0 Human T cells, 24h unstimulated, stimulated (αCD3/αCD28) 24 h + Resokine @ 1 nM Results demonstrate that Resokine has immunomodulatory activity in vitro through reduction in the extent of T cell activation. This activity is dependent on the iMod domain because the recombinant iMod domain alone, or fused to immunoglobulin Fc, has equivalent activity in these assays (data not shown). Because Resokine circulates naturally in all individuals tested, and has immuno-modulatory activity, we propose that Resokine may act as an “immune setpoint” controlling the extent of T cell activation achieved with a given stimulus.

 


 

Resokine Levels Are Elevated in Cancer Resokine levels were determined from mouse or human samples using specific immunoassays with 2 non-competing antibodies to Resokine. Assays were carried out on the MSD platform and verified using multiple formats. Upper and lower limits of quantification were established for each assay as shown in the figures. • Plasma samples from human cancer patients were obtained commercially from Conversant Bio. Plasma samples from healthy human volunteers also came from Conversant Bio, as well as Innovative Research, and some additional donated samples. Resokine Is Released From Cancer Cell Lines in Culture Circulating Resokine Levels Correlate 10000 With Tumor Volume in Mice (B16F10 Melanoma Model) 10000 1000 1000 100 100 10 1 0 Resokine (pM) Resokine Release Rate (fmol/10e6 cell/day) B16F10 4T1 CT26 EMT-6 LL/2 MC38 Pan02 Renca RM-1 0 1000 2000 3000 4000 5000 Tumor Volume (mm3) Resokine is released from cancer cell lines in culture. Levels vary from cell line to cell line. In vivo tumor growth results in increased levels of Resokine in the circulation of C57Bl6 mice bearing B16F10 tumors. • Resokine levels in serum from normal C57Bl6 mice ranged from 70 to 250pM (n = 10). Significantly higher levels (450-3000pM) were found in the serum of B16F10 tumor-bearing mice (p < 0.001). • Resokine levels are increased in proportion to tumor growth in mice, with levels increasing over 10-fold in very large tumors. Cancer Patients Have Higher Plasma Resokine Levels Plasma Resokine Levels **, p = 0.006 10000 1000 100 10 1 Normal Volunteers Oncology 18% 2% Upper Limit of Quantification 30pM Resokine Activity Level contingency analysis, p < 0.0001 Lower Limit of Quantification Plasma; Resokine ELISA; NHV: n = 148; Oncology: n = 215; Mann-Whitney Overall Resokine Levels Are Elevated in 15/15 Cancer Types ULOQ 2000 1000 600 400 200 100 60 40 20 10 6 4 18% 6% 2% (**, p = 0.0071) (****, p < 0.0001) 30pM Normal Volunteers Hematologic Solid Tumor AML B-Cell Lymphoma Brain Breast Breast (-/-/-) CLL Colorectal Follicular Lymphoma Kidney Lung Melanoma Myeloma NHV Ovarian Pancreatic Prostate Normal Volunteers n = 148; Hematology n = 100; Oncology n = 215 Fisher’s exact test; Plasma samples • Human plasma samples from patients with tumors show a higher mean level of Resokine than normal healthy volunteers, and notably few patient samples have levels of Resokine below 30pM, a level with functional activity in vitro. Extended data sets show this pattern appears to be retained across multiple tumor types. • Resokine levels in healthy volunteers (n = 148) ranged from 8pM to > 2333pM with 18% of the individuals possessing a level below 30pM. In contrast, levels measured across patients (n = 466) with all tumor types tested ranged from 20pM to > 2333pM (above the upper limit of quantification) with only 4% of the patients possessing low levels, defined as < 30pM; (p < 0.0001).

 


 

Presented at the 2018 ASCO-SITC Clinical Immuno-Oncology Symposium, January 25–27; San Francisco, CA

Is enhanced Resokine secretion used by tumors as an additional mechanism to down-regulate anti-tumor immune responses? Since levels of circulating Resokine are sufficient to modulate T cell activity, we hypothesize that the enhanced release of Resokine from tumor cells may further increase the threshold stimulation required to generate an active immune response. There is the potential for this to be an additional mechanism by which tumor cells may regulate immune responses. Anti-Resokine Antibodies Have Anti-Tumor Activity B16F10 Mouse Melanoma Syngeneic Model IgG Control Anti-PD-L1 + Anti-CTLA4 Anti-Resokine Abs 2000 2000 2000 1500 1500 1500 1000 1000 1000 500 500 500 0 0 0 0 7 14 21 0 7 14 21 0 7 14 21 Study Day Study Day Study Day Tumor Volume (mm3) Study Day 15 17 20 IgG Anti-PD-L1 Anti-RK Control + Anti-CTLA4 Abs euthanized *p < 0.05, **p < 0.01 • Anti-tumor activity was initially tested in the B16F10 syngeneic tumor model in C57Bl6 mice. B16F10 tumor cells (1x104 cells in 0.1mL PBS/20% matrigel) were implanted subcutaneously on the right flank on day 0. Antibody therapy was administered IP on days -1, 6, and 13 (200microgram/antibody/ mouse). Anti-mouse PD-L1 and anti-mouse CTLA4 antibodies were from BioXcell. Tumor volumes were measured at indicated intervals over 21 days. Statistics are 1-way ANOVA, followed by Dunnett’s. Conclusions • Resokine proteins are extracellular proteins derived from the HARS gene, including full-length HARS and a number of splice variants • Resokine proteins contain an N-terminal domain, which we have termed the iMod domain • This domain has immunomodulatory activity both in vitro (inhibition of T cell activation) and in vivo • Levels of circulating Resokine are elevated in cancer patients across multiple tumor types • Levels are also increased in mice bearing syngeneic tumors, and correlate with tumor volume • Antibodies to Resokine have demonstrated anti-tumor activity in the B16F10 syngeneic tumor model References Arif A, Terenzi F, Potdar AA, Jia J, Sacks J, China A, Halawani D, Vasu K, Li X, Brown JM, Chen J, Kozma SC, Thomas G & Fox PL (2017) EPRS is a critical mTORC1-S6K1 effector that influences adiposity in mice. Nature 542, 357-361. Lo WS, Gardiner E, Xu Z, Lau CF, Wang F, Zhou JJ, Mendlein JD, Nangle LA, Chiang KP, Yang XL, Au KF, Wong WH, Guo M, Zhang M & Schimmel P (2014) Human tRNA synthetase catalytic nulls with diverse functions. Science 345, 328-332 Park SG, Schimmel P & Kim S (2008) Aminoacyl tRNA synthetases and their connections to disease. Proc Natl. Acad. Sci. 105, 11043-11048 Wakasugi K & Schimmel P (1999) Two distinct cytokines released from a human aminoacyl-tRNA synthetase. Science 284, 147-151 Xu Z, Wei Z, Zhou JJ, Ye F, Lo WS, Wang F, Lau CF, Wu J, Nangle LA, Chiang KP, Yang XL, Zhang M & Schimmel P (2012) Internally deleted human tRNA synthetase suggests evolutionary pressure for repurposing, Structure 20, 1470-1477 Questions/Comments: please e-mail David King at: davidking@atyrpharma.com