Targeting mutated KRAS in the first-line therapy

Hideaki Ijichi
{"title":"Targeting mutated KRAS in the first-line therapy","authors":"Hideaki Ijichi","doi":"10.1002/ctd2.291","DOIUrl":null,"url":null,"abstract":"<p>KRAS is one of the most frequently mutated oncogenes in cancer.<span><sup>1</sup></span> Codon 12, 13 and 61 mutations are frequently observed as the hot spot mutations in various cancers. Normally, KRAS protein functions as a molecular switch downstream of cell surface receptors, such as epidermal growth factor receptor (EGFR), platelet-derived growth factor receptor, etc., shuttling GTP-bound active state and GDP-bound inactive state, which turns on and off the growth factors’ signals that activate MAPK, PI3K/AKT/mTOR and other signalling pathways fundamental for cell proliferation, differentiation and survival. The oncogenic mutations lock the KRAS at the active state, resulting in contributing to tumorigenesis. Genetically engineered mouse models containing tissue-specific Kras codon 12 mutation have developed clinically relevant cancers in the corresponding tissues, which indicates the central driver role of KRAS mutation in cancer formation and progression.<span>2</span></p><p>Therefore, targeting the mutated KRAS is considered an ideal therapeutic strategy in the KRAS-mutated cancers. Especially, KRAS codon 12 mutation is detected in 90% of pancreatic cancer,<span>1</span> which suggests the tumour addiction to the mutated KRAS in the most deadly cancer with a 5-year survival of still around 10%. However, KRAS has been undruggable for more than 40 years, because of its relatively smooth protein structure and lack of approachable binding pocket.<span>1</span></p><p>Recently, KRAS G12C-specific covalent inhibitors, sotorasib and adagrasib, that lock KRAS to a GDP-bound inactive state, were developed and clinically approved for the treatment of cancers with KRAS G12C mutation,<span>3</span><b><sup>,</sup></b><span>4</span> with significant therapeutic efficacy, especially in non-small cell lung cancer (NSCLC). It was a breakthrough in the field: Now, KRAS is druggable. Following them, other KRAS G12C inhibitors, as well as inhibitors specific for other KRAS mutations, have been on the line of development with growing expectations in the improvement of clinical practice.</p><p>Subsequent to the success of the KRAS G12C inhibitor, acquired resistance to the inhibitor has become a clinical problem and the underlying mechanisms have been explored.<span>5</span> Compared to NSCLC, colorectal cancer with KRAS G12C mutation showed a limited objective response to the KRAS G12C inhibitors, indicating resistance to the therapy. To overcome the resistance, combinatorial therapeutics have been investigated with the KRAS G12C inhibitors. Recently, a couple of studies demonstrated the feasibility and possible efficacy of the combination of the KRAS G12C inhibitors with EGFR inhibitors in advanced colorectal cancer.<span>6</span><b><sup>-</sup></b><span>8</span> Among them, the CodeBreaK 300, a phase 3, multicenter, open-label, randomized trial (NCT05198934) showed that a KRAS G12C-specific inhibitor sotorasib, in combination with EGFR inhibitor panitumumab, was superior to the standard treatment in progression-free survival of the patients with chemorefractory metastatic colorectal cancer, with permissible toxic effects.<span>6</span> These studies elucidated that the combinatorial inhibition of KRAS G12C and EGFR is a great strategy to overcome resistance in colorectal cancer. In line with this, another phase 3 randomized trial of adagrasib plus cetuximab, another combination of KRAS G12C inhibitor and EGFR inhibitor, is also ongoing in comparison with the standard chemotherapy in colorectal cancer with KRAS G12C mutation (KRYSTAL-10, NCT04793958).</p><p>However, unfortunately, KRAS G12C mutation is rarely detected in pancreatic cancer (1%–2%), thus, its clinical impact on pancreatic cancer is limited. In contrast, KRAS G12D is detected in 43% of pancreatic cancer patients, which is the most frequent mutation pattern, therefore, clinical approval of KRAS G12D inhibitor for pancreatic cancer is promisingly awaited. In preclinical studies, its significant impact on controlling pancreatic cancer with KRAS G12D mutation has already been confirmed,<span>9</span> indicating that it can be a striking game changer in the clinical practice of pancreatic cancer. The underlying mechanisms of resistance to the KRAS G12D inhibitor should also be considered and conquered. The combinatorial strategy with EGFR inhibitor provides insight into it.</p><p>Of note, the trials of KRAS G12C inhibitors described above as well as most of the ongoing trials with KRAS-specific inhibitors were designed for the second-line treatment setting or later, in which the previous treatment(s) should have affected the patients’ performance and the acquired chemoresistance. It is not hard to imagine that any treatment can drive resistance acquisition in cancer to a greater or lesser extent, thus the EGFR signal activation might have been caused by the previous treatment(s). Considering that KRAS mutation is a central driver of cancer formation and progression, it might be worth investigating the efficacy of mutant KRAS-specific inhibitors in the first-line treatment setting: direct targeting the driver mutation of KRAS can be more effective for the treatment-naïve cancer patients than the patients after receiving certain treatment(s). Currently, a couple of phase 3 trials using KRAS G12C inhibitor are ongoing to be approved as the first-line therapy, in addition, several phase 2 studies are also designed for the first-line or neoadjuvant setting (Table 1). The outcomes are highly anticipated, but all of them are designed only for NSCLC and there are no such trials for colorectal cancer or pancreatic cancer yet.</p><p>Meanwhile, it might also be desirable that clinical trials of KRAS G12D inhibitor, which are still in an early phase, are evaluated in the first-line setting at phase 2/3 without delay. According to the preclinical therapeutic impact of the KRAS-specific G12D inhibitor,<span>9</span> we can expect a significant improvement in the prognosis of cancer with KRAS G12D mutation: the objective response to the first-line KRAS G12D inhibitor might increase the resectability in the conversion surgery in the advanced cancer patients, especially in pancreatic cancer, most of the patients are currently unresectable state. Clinical trials take time in general, especially large-scale phase 3 trials for the clinical approval of novel therapies, whereas a number of advanced cancer patients have been waiting for highly effective therapies with hope. Hence it is extremely important that novel effective therapies are approved to be available as soon as possible through the clinical trials. The first-line treatment with KRAS-specific inhibitors (in combination with EGFR inhibitors, etc.) will significantly benefit KRAS-mutated cancer patients with currently dismal prognoses.</p><p>Hideaki Ijichi designed and wrote this manuscript.</p><p>The author declares no conflict of interest.</p><p>This manuscript is not supported by specific funding.</p><p>N/A</p><p>N/A</p>","PeriodicalId":72605,"journal":{"name":"Clinical and translational discovery","volume":"4 2","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-04-04","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1002/ctd2.291","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Clinical and translational discovery","FirstCategoryId":"1085","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1002/ctd2.291","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0

Abstract

KRAS is one of the most frequently mutated oncogenes in cancer.1 Codon 12, 13 and 61 mutations are frequently observed as the hot spot mutations in various cancers. Normally, KRAS protein functions as a molecular switch downstream of cell surface receptors, such as epidermal growth factor receptor (EGFR), platelet-derived growth factor receptor, etc., shuttling GTP-bound active state and GDP-bound inactive state, which turns on and off the growth factors’ signals that activate MAPK, PI3K/AKT/mTOR and other signalling pathways fundamental for cell proliferation, differentiation and survival. The oncogenic mutations lock the KRAS at the active state, resulting in contributing to tumorigenesis. Genetically engineered mouse models containing tissue-specific Kras codon 12 mutation have developed clinically relevant cancers in the corresponding tissues, which indicates the central driver role of KRAS mutation in cancer formation and progression.2

Therefore, targeting the mutated KRAS is considered an ideal therapeutic strategy in the KRAS-mutated cancers. Especially, KRAS codon 12 mutation is detected in 90% of pancreatic cancer,1 which suggests the tumour addiction to the mutated KRAS in the most deadly cancer with a 5-year survival of still around 10%. However, KRAS has been undruggable for more than 40 years, because of its relatively smooth protein structure and lack of approachable binding pocket.1

Recently, KRAS G12C-specific covalent inhibitors, sotorasib and adagrasib, that lock KRAS to a GDP-bound inactive state, were developed and clinically approved for the treatment of cancers with KRAS G12C mutation,3,4 with significant therapeutic efficacy, especially in non-small cell lung cancer (NSCLC). It was a breakthrough in the field: Now, KRAS is druggable. Following them, other KRAS G12C inhibitors, as well as inhibitors specific for other KRAS mutations, have been on the line of development with growing expectations in the improvement of clinical practice.

Subsequent to the success of the KRAS G12C inhibitor, acquired resistance to the inhibitor has become a clinical problem and the underlying mechanisms have been explored.5 Compared to NSCLC, colorectal cancer with KRAS G12C mutation showed a limited objective response to the KRAS G12C inhibitors, indicating resistance to the therapy. To overcome the resistance, combinatorial therapeutics have been investigated with the KRAS G12C inhibitors. Recently, a couple of studies demonstrated the feasibility and possible efficacy of the combination of the KRAS G12C inhibitors with EGFR inhibitors in advanced colorectal cancer.6-8 Among them, the CodeBreaK 300, a phase 3, multicenter, open-label, randomized trial (NCT05198934) showed that a KRAS G12C-specific inhibitor sotorasib, in combination with EGFR inhibitor panitumumab, was superior to the standard treatment in progression-free survival of the patients with chemorefractory metastatic colorectal cancer, with permissible toxic effects.6 These studies elucidated that the combinatorial inhibition of KRAS G12C and EGFR is a great strategy to overcome resistance in colorectal cancer. In line with this, another phase 3 randomized trial of adagrasib plus cetuximab, another combination of KRAS G12C inhibitor and EGFR inhibitor, is also ongoing in comparison with the standard chemotherapy in colorectal cancer with KRAS G12C mutation (KRYSTAL-10, NCT04793958).

However, unfortunately, KRAS G12C mutation is rarely detected in pancreatic cancer (1%–2%), thus, its clinical impact on pancreatic cancer is limited. In contrast, KRAS G12D is detected in 43% of pancreatic cancer patients, which is the most frequent mutation pattern, therefore, clinical approval of KRAS G12D inhibitor for pancreatic cancer is promisingly awaited. In preclinical studies, its significant impact on controlling pancreatic cancer with KRAS G12D mutation has already been confirmed,9 indicating that it can be a striking game changer in the clinical practice of pancreatic cancer. The underlying mechanisms of resistance to the KRAS G12D inhibitor should also be considered and conquered. The combinatorial strategy with EGFR inhibitor provides insight into it.

Of note, the trials of KRAS G12C inhibitors described above as well as most of the ongoing trials with KRAS-specific inhibitors were designed for the second-line treatment setting or later, in which the previous treatment(s) should have affected the patients’ performance and the acquired chemoresistance. It is not hard to imagine that any treatment can drive resistance acquisition in cancer to a greater or lesser extent, thus the EGFR signal activation might have been caused by the previous treatment(s). Considering that KRAS mutation is a central driver of cancer formation and progression, it might be worth investigating the efficacy of mutant KRAS-specific inhibitors in the first-line treatment setting: direct targeting the driver mutation of KRAS can be more effective for the treatment-naïve cancer patients than the patients after receiving certain treatment(s). Currently, a couple of phase 3 trials using KRAS G12C inhibitor are ongoing to be approved as the first-line therapy, in addition, several phase 2 studies are also designed for the first-line or neoadjuvant setting (Table 1). The outcomes are highly anticipated, but all of them are designed only for NSCLC and there are no such trials for colorectal cancer or pancreatic cancer yet.

Meanwhile, it might also be desirable that clinical trials of KRAS G12D inhibitor, which are still in an early phase, are evaluated in the first-line setting at phase 2/3 without delay. According to the preclinical therapeutic impact of the KRAS-specific G12D inhibitor,9 we can expect a significant improvement in the prognosis of cancer with KRAS G12D mutation: the objective response to the first-line KRAS G12D inhibitor might increase the resectability in the conversion surgery in the advanced cancer patients, especially in pancreatic cancer, most of the patients are currently unresectable state. Clinical trials take time in general, especially large-scale phase 3 trials for the clinical approval of novel therapies, whereas a number of advanced cancer patients have been waiting for highly effective therapies with hope. Hence it is extremely important that novel effective therapies are approved to be available as soon as possible through the clinical trials. The first-line treatment with KRAS-specific inhibitors (in combination with EGFR inhibitors, etc.) will significantly benefit KRAS-mutated cancer patients with currently dismal prognoses.

Hideaki Ijichi designed and wrote this manuscript.

The author declares no conflict of interest.

This manuscript is not supported by specific funding.

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在一线疗法中靶向突变的 KRAS
1 密码子 12、13 和 61 突变是各种癌症中经常出现的热点突变。正常情况下,KRAS 蛋白在表皮生长因子受体(EGFR)、血小板衍生生长因子受体等细胞表面受体的下游起着分子开关的作用,在 GTP 结合的活性状态和 GDP 结合的非活性状态之间穿梭,从而开启或关闭生长因子信号,激活 MAPK、PI3K/AKT/mTOR 等信号通路,这些信号通路对细胞增殖、分化和存活至关重要。致癌突变将 KRAS 锁定在活性状态,导致肿瘤发生。含有组织特异性 Kras 第 12 号密码子突变的基因工程小鼠模型已在相应的组织中发生了临床相关的癌症,这表明 KRAS 突变在癌症的形成和发展中起着核心驱动作用。特别是在 90% 的胰腺癌中检测到了 KRAS 第 12 号密码子突变,1 这表明肿瘤对突变的 KRAS 上瘾,而这种最致命的癌症的 5 年生存率仍在 10% 左右。1 最近,KRAS G12C 特异性共价抑制剂 sotorasib 和 adagrasib 被开发出来并获得临床批准,用于治疗 KRAS G12C 突变的癌症,3,4 疗效显著,尤其是在非小细胞肺癌(NSCLC)中。这是该领域的一项突破:现在,KRAS 可以被药物治疗了。继 KRAS G12C 抑制剂取得成功后,获得性耐药性已成为一个临床问题,人们开始探索其背后的机制。5 与 NSCLC 相比,KRAS G12C 突变的结直肠癌对 KRAS G12C 抑制剂的客观反应有限,这表明该疗法存在耐药性。为了克服耐药性,人们研究了 KRAS G12C 抑制剂的组合疗法。最近,几项研究证明了 KRAS G12C 抑制剂与表皮生长因子受体抑制剂联合治疗晚期结直肠癌的可行性和可能的疗效。其中,CodeBreaK 300 是一项 3 期、多中心、开放标签、随机试验(NCT05198934),结果显示 KRAS G12C 特异性抑制剂 sotorasib 与表皮生长因子受体抑制剂帕尼单抗联用,在化疗难治性转移性结直肠癌患者的无进展生存期方面优于标准治疗,且毒副作用在允许范围内。这些研究阐明,联合抑制 KRAS G12C 和表皮生长因子受体(EGFR)是克服结直肠癌耐药性的最佳策略。与此相呼应,阿达拉昔布联合西妥昔单抗(另一种 KRAS G12C 抑制剂和表皮生长因子受体(EGFR)抑制剂的联合疗法)的 3 期随机试验也在进行中,该试验与 KRAS G12C 突变的结直肠癌标准化疗进行了比较(KRYSTAL-10,NCT04793958)。相比之下,43%的胰腺癌患者可检测到 KRAS G12D,这是最常见的突变模式,因此,临床上有望批准 KRAS G12D 抑制剂用于胰腺癌。在临床前研究中,KRAS G12D 抑制剂对控制 KRAS G12D 突变的胰腺癌的显著效果已得到证实,9 这表明它可以在胰腺癌的临床实践中起到引人注目的改变作用。对 KRAS G12D 抑制剂产生耐药性的根本机制也应加以考虑和攻克。值得注意的是,上文所述的 KRAS G12C 抑制剂试验以及大多数正在进行的 KRAS 特异性抑制剂试验都是针对二线治疗或二线以后的治疗而设计的,在二线治疗或二线以后的治疗中,先前的治疗应该已经影响了患者的表现和获得性化疗耐药性。不难想象,任何治疗都会或多或少地导致癌症产生耐药性,因此表皮生长因子受体信号的激活可能是由之前的治疗引起的。
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