Multiple Posters Highlight the Breadth of Company's Novel Genetic Medicine and Cell Therapy Platforms
LONDON and NEW YORK, Oct. 22, 2024 (GLOBE NEWSWIRE) -- MeiraGTx Holdings plc (Nasdaq: MGTX), a vertically integrated, clinical-stage genetic medicines company, today announced the Company will exhibit five posters at the European Society of Gene and Cell Therapy (ESGCT) 2024 Annual Congress, which is being held from October 22-25, 2024, in Rome, Italy.
The posters are available on the Posters and Publications page of the Company's website.
The details of the poster presentations are as follows:
Poster Number: P0015
Abstract Title: Evolution of a high-producing, modular upstream platform for AAV manufacturing
Poster Session III: Tuesday 22 October from 19:30 to 21:00 CEST
Abstract:
The poster shows the evolution of MeiraGTx's upstream manufacturing platform, which was optimized and modulated through the choice of transfection reagents, adeno-associated virus (AAV) production enhancers, and transfection parameters, in fed-batch and perfusion culture mode. Over 3 years, we have achieved process optimizations yielding AAV titers up to 1x1012 VG/mL at harvest and >40% full capsids prior to polishing purification steps. Product quality attributes such as encapsidated residual plasmid DNA and host cell DNA are demonstrated to be controllable and maintained to satisfactory levels for patient safety through the combination of transfection reagent, small molecule enhancer, and transfection mix formulation parameters. Operating a perfusion-based process has also increased volumetric VG yield by approximately 40% and reduced plasmid DNA usage by at least 25%, without compromising on AAV productivity and product quality, demonstrating additional cost savings.
Poster Number: P0020
Abstract Title: AAV-based evaluation of novel in silico promoters to drive expression in rod photoreceptors
Poster Session II: Wednesday 23 October from 13:30 to 15:00 CEST
Abstract:
As rods outnumber cones by a ratio of 1:20 or greater in the retina and defects are common in rods leading to various ocular diseases, we sought to design and test novel promoters to drive expression specifically and at high expression levels in rods. Using an AI-assisted promoter engineering approach, ten novel promoter sequences were initially designed, cloned into an adeno-associated virus (AAV) backbone carrying eGFP and finally packaged into AAV5 or AAV7m8. In addition, AAV5 and AAV7m8 vectors were produced carrying the commonly used rhodopsin kinase (RK) promoter and eGFP. Following the initial screen, five second-generation, improved promoter sequences were designed combining elements from preferred performers of the first screen and again packaged into AAV5 and AAV7m8 for additional analysis. Wild-type mice received subretinal injections with the AAV5 vectors to assess promoter activity in the murine retina. Four weeks post vector administration, eyes were harvested for immunohistochemical analysis and qPCR expression analysis to determine specificity and expression levels, respectively. In parallel, the AAV7m8 vectors were used to assess promoter activity in human pluripotent stem cell (hPSC)-derived retinal organoids. Three weeks post-transduction, organoids were fixed and dissociated into single cells for FACS analysis or cryosectioned for immunohistochemistry. Sections were stained with markers of rod and cone photoreceptors and quantitatively assessed for eGFP co-expression. Lead candidates were identified based on promoter specificity to rod photoreceptors, determined by immunohistochemistry, and promoter strength, measuring expression level using qPCR or signal intensity using FACS.
Poster Number: P0129
Abstract Title: Identification of highly potent and tissue-specific promoters with massively parallel screening
Poster Session III: Tuesday 22 October from 19:30 to 21:00 CEST
Abstract:
Promoters are an integral component of any effective gene therapy. A potent promoter may allow for a therapeutic effect with a lower dosage, which could lower immune responses and manufacturing costs. A short promoter leaves more space for the transgene and mitigates the cargo capacity constraints of current gene therapy delivery methods. In addition, shorter promoters are especially useful for central nervous system applications as neuronal genes tend to have a longer coding region compared to non-neuronal genes. Here, we developed a massively parallel reporter assay (MPRA) to screen a synthetic library of over 240,000 promoters that are 182 bp long. This flexible AAV-based platform can be applied to diverse model systems including primary human tissue, iPSC-derived organoids, and non-human primates. Initial screening in transfected mouse Neuro2A cells identified hundreds of potent promoter candidates, of which 34 were selected for independent validation using flow cytometry. We identified 15 promoters exhibiting folds higher expression than CAG despite a 10-fold reduction in size in Neuro2A cells. Furthermore, 5 of these promoters are stronger than CMV and 3-fold smaller. In the human Huh7 cell line, all 15 promoters have lower expression than CAG indicating their specificity. In parallel, potent promoters were identified by this platform in human myotubes, primary mouse neurons, mouse liver, and the mouse gastrocnemius muscle. Independent validation of single candidates confirms the strength of our candidate promoters in vivo. These selected promoters can be further engineered using machine learning coupled with rational design to increase promoter potency. This approach allows the screening of hundreds of thousands of rationally designed small promoters (<200bp) capable of driving strong transgene expression in complex model systems. Our selected promoters harbor great potential for future gene therapy applications.
Poster Number: P0351
Abstract Title: AAV-mediated gene therapy attenuates loss of vision in a mouse model of Bardet-Biedl-Syndrome 10
Poster Session I: Tuesday 22 October from 19:30 to 21:00 CEST
Abstract:
Bardet-Biedl syndrome (BBS) is a group of inherited, autosomal recessive ciliopathies characterized by disturbances of cilia function in multiple cell types, leading to obesity, renal failure, and blindness. More than 20 causative genes are known with many mutations disabling the function of the BBSome, a protein complex regulating the movement of cargo proteins in and out of cilia. Mutations in the BBS10 gene are the second most common cause of BBS and account for more than 20% of all cases. In this study, we set out to optimize and identify an AAV vector carrying the human BBS10 gene providing sustained efficacy and a good safety profile for clinical translation.
Human BBS10 either under the control of the ubiquitous CAG promoter or the photoreceptor-specific rhodopsin kinase (RK) promoter was packaged into AAV8 and tested in Bbs10 KO mice at different doses. Whilst the CAG construct did not show efficacy, treatment with the RK construct rescued retinal function and thickness up to six months post-treatment when delivered at a high dose, accompanied by a partial correction of the localization of Syntaxin 3, a partner protein of BBS10. Interestingly, a 5-fold lower dose of AAV8.RK.hBBS10 was not therapeutic, although the equivalent dose of an AAV8.RK carrying mouse Bbs10 was efficacious. These findings support the hypothesis that due to a species difference, the potency of the AAV8.RK.hBBS10 is potentially underestimated when assessed in Bbs10 KO mice. In parallel to the work in mutants, we performed a long-term safety study to overexpress human BBS10 under the RK promoter in wild-type mice. Up to six months post-injection, no significant detrimental effects on retinal function or retinal morphology were observed paving the way toward translation. Application for rare pediatric disease designation is currently underway.
Poster Number: P0753
Abstract Title: Riboswitch-regulated gene and cell therapy
Poster Session III: Thursday 24 October from 14:00 to 15:30 CEST
Abstract:
Controlled expression of delivered transgene is critical for both gene and cell therapies. Here, we report that by linking our synthetic aptamer to our alternative splicing gene expression platform, we have created a robust, synthetic mammalian riboswitch cassette that regulates gene expression tightly and dynamically in response to small-molecule inducers. In the presence of the small molecule, the splicing-based expression platform creates an "on" switch by sequestering a splice site of an alternative exon. Riboswitches that respond to these novel small-molecule inducers regulate transgene expression with high dynamic range in a dose-dependent manner. When delivered through an adeno-associated viral (AAV) vector to the liver or the muscle in mice, the engineered riboswitches reversibly regulate transgene expression via an orally delivered small-molecule inducer, providing precise control of transgene expression, with high dynamic range. With these riboswitches and orally available small-molecule inducers, we were able to regulate hormones such as human growth hormone, growth factors such as erythropoietin (Epo), and therapeutic antibodies such as anti-HER2 antibodies to efficacious levels in vivo. RiboCAR-T cells with riboswitch-controlled chimeric antigen receptors (CARs) had more stem/memory-like phenotypes, exhibiting superior anti-tumor activities against lymphoma when compared with conventional CAR-T cells that expressed constitutive CAR.
This robust gene regulation system enables both temporal and spatial control of gene expression, providing not only improved efficacy but also a safety mechanism for gene and cell therapies.
About MeiraGTx
MeiraGTx (Nasdaq: MGTX) is a vertically integrated, clinical-stage genetic medicines company with a broad pipeline of late-stage clinical programs supported by end-to-end manufacturing capabilities. MeiraGTx has internal plasmid production for GMP, two GMP viral vector production facilities as well as an in-house Quality Control hub for stability and release, all fit for IND through commercial supply. In addition, MeiraGTx has developed a proprietary manufacturing platform with leading yield and quality aspects and commercial readiness, core capabilities in viral vector design and optimization, and a transformative riboswitch gene regulation platform technology that allows for the precise, dose-responsive control of gene expression by oral small molecules. MeiraGTx is focusing the riboswitch platform on the delivery of metabolic peptides, including GLP-1, GIP, Glucagon, and PYY, using oral small molecules, as well as cell therapy for oncology and autoimmune diseases. MeiraGTx has developed the technology to apply genetic medicine to more common diseases, increasing efficacy, addressing novel targets, and expanding access in some of the largest disease areas where the unmet need remains high.
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Forward Looking Statement
This press release contains forward-looking statements within the meaning of the Private Securities Litigation Reform Act of 1995. All statements contained in this press release that do not relate to matters of historical fact should be considered forward-looking statements, including, without limitation, statements regarding our product candidate development and anticipated milestones regarding our pre-clinical and clinical data, reporting of such data and the timing of results of data and regulatory matters, as well as statements that include the words "expect," "will," "intend," "plan," "believe," "project," "forecast," "estimate," "may," "could," "should," "would," "continue," "anticipate" and similar statements of a future or forward-looking nature. These forward-looking statements are based on management's current expectations. These statements are neither promises nor guarantees, but involve known and unknown risks, uncertainties and other important factors that may cause actual results, performance or achievements to be materially different from any future results, performance or achievements expressed or implied by the forward-looking statements, including, but not limited to, our incurrence of significant losses; any inability to achieve or maintain profitability, raise additional capital, repay our debt obligations, identify additional and develop existing product candidates, successfully execute strategic transactions or priorities, bring product candidates to market, expansion of our manufacturing facilities and processes, successfully enroll patients in and complete clinical trials, accurately predict growth assumptions, recognize benefits of any orphan drug designations, retain key personnel or attract qualified employees, or incur expected levels of operating expenses; the impact of pandemics, epidemics, or outbreaks of infectious diseases on the status, enrollment, timing and results of our clinical trials and on our business, results of operations and financial condition; failure of early data to predict eventual outcomes; failure to obtain FDA or other regulatory approval for product candidates within expected time frames or at all; the novel nature and impact of negative public opinion of gene therapy; failure to comply with ongoing regulatory obligations; contamination or shortage of raw materials or other manufacturing issues; changes in healthcare laws; risks associated with our international operations; significant competition in the pharmaceutical and biotechnology industries; dependence on third parties; risks related to intellectual property; changes in tax policy or treatment; our ability to utilize our loss and tax credit carryforwards; litigation risks; and the other important factors discussed under the caption "Risk Factors" in our Quarterly Report on Form 10-Q for the quarter ended June 30, 2024, as such factors may be updated from time to time in our other filings with the SEC, which are accessible on the SEC's website at www.sec.gov. These and other important factors could cause actual results to differ materially from those indicated by the forward-looking statements made in this press release. Any such forward-looking statements represent management's estimates as of the date of this press release. While we may elect to update such forward-looking statements at some point in the future, unless required by law, we disclaim any obligation to do so, even if subsequent events cause our views to change. Thus, one should not assume that our silence over time means that actual events are bearing out as expressed or implied in such forward-looking statements. These forward-looking statements should not be relied upon as representing our views as of any date subsequent to the date of this press release.
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多個海報突出公司新穎的基因藥物和細胞療法平台的廣度
倫敦和紐約,2024年10月22日(環球新聞社)- 美瑞基因電力控股有限公司(Nasdaq: MGTX)是一家垂直一體化的臨床階段基因藥物公司,今天宣佈該公司將在2024年歐洲基因與細胞治療學會(ESGCT)年會上展示五個海報,該會議將於2024年10月22日至25日在意大利羅馬舉行。
這些海報可在公司網站的海報和出版物頁面上找到。
海報展示的詳細信息如下:
海報編號:P0015
摘要標題: AAV製造的高產、模塊化上游平台的演進
海報展示III: 歐洲中部時間10月22日星期二晚上19:30至21:00
摘要:
海報展示了MeiraGTx的上游製造平台的演變,通過選擇轉染試劑、腺相關病毒(AAV)生產增強劑和轉染參數,在fed-batch和perfusion培養模式下進行了優化和調節。在3年的時間裏,我們實現了工藝優化,使得AAV滴度在收穫時可達1x10^12個VF/mL,達到超過40%的全衣殼前體,在精煉淨化步驟之前。產品質量屬性,如胞內殘留質粒DNA和宿主細胞DNA,通過轉染試劑、小分子增強劑和轉染混合物配方參數的組合,被證明是可控的,並保持在滿足患者安全水平的滿意水平。採用灌流工藝的操作還將體積型VG產量提高了約40%,並將質粒DNA使用量降低至少25%,同時不影響AAV生產率和產品質量,展示了額外的成本節約。
海報編號: P0020
摘要標題: 基於AAV的評估,利用新型計算機提前設計的啓動子在桿狀光感受器中進行表達
海報展示II: 歐洲中部時間10月23日星期三下午13:30至15:00
摘要:
視網膜中杆比錐的比例爲1:20或更大,且常見的杆細胞缺陷導致各種眼部疾病,因此我們試圖設計並測試新型啓動子,以在杆細胞中特異性地並且高表達水平驅動表達。利用人工智能輔助啓動子工程方法,最初設計了十個新型啓動子序列,並將其克隆到攜帶eGFP的腺相關病毒(AAV)骨架中,最後打包成AAV5或AAV7m8。此外,製備了攜帶常用視紫紅素激酶(RK)啓動子和eGFP的AAV5和AAV7m8載體。在初篩後,設計了五個第二代改進啓動子序列,結合第一輪首選表現者的元素,並再次打包入AAV5和AAV7m8進行額外分析。野生型小鼠接受次視網膜注射AAV5載體,以評估啓動子在小鼠視網膜中的活性。給藥後四周,收集眼睛進行免疫組化分析和qPCR表達分析,以分別確定特異性和表達水平。同時,使用AAV7m8載體評估啓動子在人類多能幹細胞(hPSC)衍生的視網膜器官樣體中的活性。轉導後三週,器官樣體固定並分離成單個細胞以進行FACS分析,或冷凍切片進行免疫組化。切片用桿狀和錐狀感光細胞標記染色,並定量評估eGFP的共表達。基於免疫組化確定的啓動子對桿狀感光細胞的特異性,以及使用qPCR或FACS測量表達水平來衡量啓動子強度,鑑定了領先候選者。
發帖編號:P0129
摘要標題:鑑定高效特異性啓動子並進行大規模並行篩選
發帖時間III:歐洲中部夏令時間10月22日星期二,從19:30至21:00
摘要:
啓動子是任何有效基因治療的重要組成部分。強效啓動子可能允許以更低劑量產生治療效應,從而降低免疫反應和製造成本。短啓動子留下更多的空間供轉基因使用,並減輕當前基因治療傳遞方法的載體容量限制。此外,相較於非神經元基因,較短的啓動子特別適用於中樞神經系統應用,因爲神經元基因傾向於具有較長的編碼區域。在這裏,我們開發了一個用於篩選240,000多個長爲182bp的合成啓動子的大規模並行報告基因分析(MPRA)。這種靈活的基於AAV的平台可應用於包括原代人類組織、iPSC衍生的器官樣體和非人靈長類動物在內的不同模型系統。在轉染小鼠神經元2A細胞中的初篩中鑑定了數百個潛在強效啓動子候選者,其中34個通過流式細胞術被選擇進行獨立驗證。我們確定了15個啓動子在神經元2A細胞中的表達水平比CAG高出數倍,儘管尺寸減小了10倍。此外,這些啓動子中有5個比CMV更強大且尺寸縮小了3倍。在人類Huh7細胞系中,所有15個啓動子的表達水平都低於CAG,表明它們的特異性。同時,通過這種平台在人類肌肉細胞、原代小鼠神經元、小鼠肝臟和小鼠腓腸肌中鑑定了強效啓動子。獨立驗證單個候選者進一步確認了我們候選啓動子在體內的強度。這些選定的啓動子可以通過機器學習結合合理設計進行進一步工程處理,以增加啓動子的強效性。這種方法可以篩選成百上千個經過合理設計的小啓動子(<200bp),能夠在複雜模型系統中產生強大的轉基因表達。我們所選的啓動子具有未來基因治療應用的巨大潛力。
發帖號:P0351
摘要標題: 通過AAV介導的基因治療減輕巴代特-比德爾綜合徵10型小鼠視力喪失
發帖會話I:CEST時間10月22日星期二晚上7:30至9:00
摘要:
巴代特-比德爾綜合徵(BBS)是一組遺傳性的常染色體隱性纖毛病,其特徵是多種細胞類型中纖毛功能紊亂,導致肥胖、腎功能衰竭和失明。已知超過20種致病基因,許多突變破壞了BBSome的功能,這是一個調節將貨物蛋白進出纖毛的蛋白複合物。BBS10基因突變是BBS的第二常見原因,佔所有病例的20%以上。在這項研究中,我們致力於優化和確定攜帶人類BBS10基因的AAV載體,以提供持續的療效和良好的安全性,用於臨床轉化。
人類BBS10基因分別在普遍存在的CAG啓動子或視網膜特異性的視紫紅蛋白激酶(RK)啓動子的控制下,被封裝到AAV8中,並在不同劑量下在Bbs10KO小鼠中進行了測試。雖然CAG結構未顯示療效,但使用Rk構建物治療可以在給藥後半年內拯救視網膜功能和厚度,伴隨着BBS10的合作蛋白Syntaxin 3的定位部分糾正。有趣的是,AAV8.Rk.hBBS10的5倍低劑量並非治療性,儘管AAV8.Rk攜帶小鼠Bbs10的等效劑量具有療效。這些發現支持了由於物種差異,AAV8.Rk.hBBS10的效力在Bbs10KO小鼠中評估時可能被低估的假設。與突變體的工作同時進行,我們在野生型小鼠中使用Rk啓動子過度表達人類BBS10進行了長期安全性研究。在注射後長達六個月內,沒有觀察到對視網膜功能或形態的顯着不良影響,爲轉化鋪平了道路。罕見兒童疾病認定申請目前正在進行中。
發帖編號: P0753
摘要標題: 核酸開關調控的基因和細胞療法
發帖會話III: 10月24日星期四,中歐夏令時間14:00至15:30
摘要:
傳遞的轉基因的受控表達對於基因和細胞療法至關重要。在這裏,我們報告稱,通過將我們的合成適配體與我們的選擇性剪接基因表達平台連接,我們創建了一個穩健的、合成的哺乳動物核糖開關基因組,該基因組可以根據小分子誘導劑緊密而動態地調節基因表達。在存在小分子的情況下,基於剪接的表達平台通過封閉一種選擇性外顯子的剪接位點來創建一個「開啓」開關。對這些新型小分子誘導劑響應的核糖開關以劑量依賴方式調節轉基因表達,並具有很高的動態範圍。通過腺相關病毒(AAV)載體傳遞到小鼠的肝臟或肌肉中,利用口服小分子誘導劑,精確控制轉基因表達的工程核糖開關可可逆地調節轉基因的表達,從而實現很高的動態範圍。藉助這些核糖開關和易購得的口服小分子誘導劑,我們能夠將激素如人類生長激素、生長因子如促紅細胞生成素(EPO)以及抗HER2抗體等治療性抗體在體內有效水平地調節。具有受核糖開關控制的嵌合抗原受體(CARs)的RiboCAR-t細胞具有更多幹/記憶樣表型,與常規表達具有恒定CAR的CAR-t細胞相比,對抗淋巴瘤的抗腫瘤活性更強。
這種穩健的基因調控系統不僅能夠實現基因表達的時間和空間控制,提供了不僅提高了療效還提供了基因和細胞療法的安全機制。
關於MeiraGTx
MeiraGTx(納斯達克:MGTX)是一家垂直整合的臨床前基因藥公司,擁有廣泛的後期臨床項目管線,支持端到端製造能力。 MeiraGTx擁有內部質粒生產的GMP,兩個GMP病毒載體生產設施,以及一個內部質量控制中心用於穩定性和釋放,所有適用於IND到商業供應。此外,MeiraGTx開發了一種專有的製造平台,具有領先的產量和質量方面以及商業準備性,核心能力在病毒載體設計和優化,以及一種革新的核糖開關基因調控平台技術,該技術允許通過口服小分子精確,劑量響應性地控制基因表達。MeiraGTx將核糖開關平台專注於輸送代謝肽,包括GLP-1、GIP、胰高血糖素和PYY,使用口服小分子以及用於腫瘤學和自體免疫疾病的細胞療法。MeiraGTx已經開發了將基因藥物應用於更常見疾病的技術,提高了療效,解決了新穎靶點,並在一些最大的疾病領域擴大了未滿足需求的提供。
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前瞻性聲明
本新聞稿包含根據1995年《1995年私人證券訴訟改革法案》的前瞻性聲明。本新聞稿中所有與歷史事實無關的聲明均應視爲前瞻性聲明,包括但不限於關於我們產品候選品的開發和有關我們臨床前和臨床數據的預期里程碑的聲明,報告此類數據以及數據結果和監管事宜的時間安排,以及包含"期望"、"將"、"打算"、"計劃"、"相信"、"計劃"、"預測"、"估計"、"可能"、"可以"、"應該"、"將繼續"、"預測"、"預期"和類似表述未來或前瞻性性質的聲明。這些前瞻性聲明基於管理層的當前期望。這些聲明既非承諾也非保證,但涉及已知和未知的風險、不確定性和其他重要因素,可能導致實際結果、表現或成就與前瞻性聲明中明示或暗示的任何未來結果、表現或成就有重大差異,包括但不限於我們承擔巨大損失;無法實現或維持盈利能力,籌集額外資本,償還債務,確定並發展現有產品候選品,成功執行戰略交易或優先事項,推出產品候選品,擴大製造設施和流程,成功招募病人並完成臨床試驗,準確預測增長假設,認可任何孤兒藥品認定的益處,保留關鍵人員或吸引合格僱員,或發生預期水平的營業費用;大流行病、流行病或傳染病的爆發對我們臨床試驗的狀態、招募、時間安排以及對我們業務、運營和財務狀況的影響;早期數據無法預測最終結果;未能按預期時間框架或根本獲得FDA或其他監管機構批准產品候選品;基因治療負面公衆意見的新穎性和影響導致不遵守持續性監管義務;原料污染或短缺或其他製造問題;醫療保健法律變化;與我們國際運營有關的風險;製藥和生物技術行業的激烈競爭;依賴於第三方;知識產權相關風險;稅收政策或待遇變化;我們利用稅前虧損和稅收抵免的能力;訴訟風險;以及在我們2024年6月30日的第10-Q季度報告清單下討論的其他重要因素,這些因素可能會隨時間而更新在SEC網站www.sec.gov上可訪問。這些和其他重要因素可能導致實際結果與本新聞稿中提出的前瞻性聲明所示的結果之間存在重大差異。上述前瞻性聲明代表管理層截至本新聞稿日期的估計。儘管未來某個時候我們可能選擇更新這類前瞻性聲明,但除非法律要求,我們不承擔任何更新這類聲明的義務,即使隨後事件導致我們的觀點發生變化。因此,人們不應假設我們隨着時間的推移保持沉默就意味着實際事件如此表達或暗示在這類前瞻性聲明中。不應依賴於這些前瞻性聲明作爲代表我們觀點截至本新聞稿日期之後任何日期的依據。
聯繫方式
投資者:
MeiraGTx屬於Zacks的醫療-生物醫藥和遺傳學行業,其在截至2024年6月的季度營業收入爲$28萬,較Zacks共識預期低98.28%,去年同期營業收入爲$354萬。公司在過去四個季度中只有一次超過共識營收預期。
Investors@meiragtx.com
或者
媒體:
Jason Braco, Ph.D.
通信-半導體
jbraco@lifescicomms.com
