Bcl-2 B细胞淋巴瘤2（鼠单克隆抗体）

广州健仑生物科技有限公司

弥漫大B细胞淋巴瘤是NHL中zui常见的类型，几乎占所有病例的1/3。这类淋巴瘤占以前临床上的“侵袭性”或“中高度恶性”淋巴瘤的大多数病例。弥漫大B细胞淋巴瘤正确的诊断需要血液病理学专家根据合适的活检和B细胞免疫表型的证据而得出。近年多个多中心随机对照临床试验研究资料证明，其标准的一线治疗方案应当是利妥昔单抗(Rituximab,R)+CHOP方案，并且通过增加方案的剂量密度，缩短疗程间隙时间，从而获得更好的疗效，如R-CHOP14 方案。

我司还提供其它进口或国产试剂盒：登革热、疟疾、流感、A链球菌、合胞病毒、腮病毒、乙脑、寨卡、黄热病、基孔肯雅热、克锥虫病、违禁品滥用、肺炎球菌、军团菌、化妆品检测、食品安全检测等试剂盒以及日本生研细菌分型诊断血清、德国SiFin诊断血清、丹麦SSI诊断血清等产品。

欢迎咨询

欢迎咨询

【产品介绍】

细胞定位：细胞膜/细胞浆

克隆号：124

同型：IgG1/K

适用组织：石蜡/冰冻

阳性对照：弥漫性大B细胞淋巴瘤

抗原修复：热修复（EDTA）

抗体孵育时间：30-60min

Bcl-2 B细胞淋巴瘤2（鼠单克隆抗体）

分类
酒类酵母分为酒精酵母、生香酵母、威士忌酵母。酒精酵母又分为小曲酒酵母、大曲酒酵母、小麦酒精酵母、甘蔗酒精酵母。
酿酒酵母(Saccharomyces cerevisiae)，又称面包酵母或出芽酵母。酿酒酵母是与人类关系zui广泛的一种酵母，不仅因为传统上它用于制作面包和馒头等食品及酿酒，在现代分子和细胞生物学中用作真核模式生物，其作用相当于原核的模式生物大肠杆菌。酿酒酵母是发酵中zui常用的生物种类。酿酒酵母的细胞为球形或者卵形，直径5–10μm。其繁殖的方法为出芽生殖。
酿酒酵母是*个完成基因组测序的真核生物，测序工作于1996年完成[3]  。
酿酒酵母的基因组包含大约1200万碱基对，分成16组染色体，共有6275个基因，其中可能约有5800个真正具
有功能。据估计其基因约有23%与人类同源。酵母基因组数据库包含有酵母基因组的详细注释（annotation），是研究真核细胞遗传学和生理学的重要工具。另一个重要的酿酒酵母数据库[1]由慕尼黑蛋白质序列信息中心维护。
在酿酒酵母测序计划开始之前，人们通过传统的遗传学方法已确定了酵母中编码RNA或蛋白质的大约2600个基因。通过对酿酒酵母的完整基因组测序，发现在12068kb的全基因组序列中有5885个编码专一性蛋白质的开放阅读框。这意味着在酵母基因组中平均每隔2kb就存在一个编码蛋白质的基因，即整个基因组有72%的核苷酸顺序由开放阅读框组成。这说明酵母基因比其它高等真核生物基因排列紧密。如在线虫基因组中，平均每隔6kb存在一个编码蛋白质的基因；在人类基因组中，平均每隔30kb或更多的碱基才能发现一个编码蛋白质的基因。酵母基因组的紧密性是因为基因间隔区较短与基因中内含子稀少。酵母基因组的开放阅读框平均长度为1450bp即483个密码子，zui长的是位于Ⅻ号染色体上的一个功能未知的开放阅读框（4910个密码子），还有极少数的开放阅读框长度超过1500个密码子。在酵母基因组中，也有编码短蛋白的基因，例如，编码由40个氨基酸组成的细胞质膜蛋白脂质的PMP1基因。此外，酵母基因组中还包含：约140个编码RNA的基因，排列在Ⅻ号染色体的长末端；40个编码SnRNA的基因，散布于16条染色体；属于43个家族的275个tRNA基因也广泛分布于基因组中。表1提供了酵母基因在各染色体上分布的大致情况。

Bcl-2

我司还提供其它进口或国产试剂盒：登革热、疟疾、流感、A链球菌、合胞病毒、腮病毒、乙脑、寨卡、黄热病、基孔肯雅热、克锥虫病、违禁品滥用、肺炎球菌、军团菌、化妆品检测、食品安全检测等试剂盒以及日本生研细菌分型诊断血清、德国SiFin诊断血清、丹麦SSI诊断血清等产品。

想了解更多的产品及服务请扫描下方二维码：

【公司名称】 广州健仑生物科技有限公司
【市场部】    杨永汉

【】 
【腾讯  】 
【公司地址】 广州清华科技园创新基地番禺石楼镇创启路63号二期2幢101-103室

classification
Wine yeast is divided into alcohol yeast, raw yeast, whiskey yeast. Alcohol yeast is divided into small song yeast, Daqu liquor yeast, wheat alcohol yeast, sugar cane alcohol yeast.
Saccharomyces cerevisiae, also known as baker's yeast or budding yeast. Saccharomyces cerevisiae is the yeast with the most extensive relationship with human beings. Not only is it traditionally used for making food such as bread and steamed bread, but also as a eukaryotic model organism in modern molecular and cell biology. Its function is equivalent to that of prokaryotic Pattern of biological E. coli. Saccharomyces cerevisiae is the most commonly used biological species in fermentation. The cells of Saccharomyces cerevisiae are spherical or ovate and 5-10 μm in diameter. The breeding method for budding reproductive.
Saccharomyces cerevisiae was the first eukaryotic to complete genome sequencing and the sequencing was completed in 1996 [3].
The genome of Saccharomyces cerevisiae contains about 12 million base pairs, is divided into 16 groups of chromosomes, a total of 6275 genes, of which there may be about 5800 real
Functional. It is estimated that about 23% of its genes are homologous to humans. The yeast genome database contains detailed annotations of the yeast genome and is an important tool for studying eukaryotic cytogenetics and physiology. Another important Saccharomyces database [1] is maintained by the Munich Protein Sequence Information Center.
Prior to the Saccharomyces cerevisiae sequencing program, about 2,600 genes encoding RNA or protein in yeast have been identified by conventional genetic methods. Through the complete genome sequencing of Saccharomyces cerevisiae, 5885 open reading frames (ORFs) encoding specific proteins were found in the entire genome sequence of 12068kb. This means that on average every 2kb in the yeast genome there is a gene that encodes a protein, ie 72% of the nucleotide sequence of the entire genome consists of an open reading frame. This shows that the yeast gene is more closely related to other higher eukaryotes. As in the nematode genome, there is an average of one protein-coding gene at every 6kb; in the human genome, an average of 30kb or more of the base is required to find a gene encoding a protein. The tightness of the yeast genome is due to the short intergenic spacer and the rare intron in the gene. The yeast genome has an open reading frame of 1450 bp or 483 codons in length, with the longest open reading frame (4,910 codons) located on chromosome number one and a very small number of open reading frames longer than 1500 codons. Among the yeast genome, there are also genes encoding short proteins, for example, the PMP1 gene encoding a plasma membrane protein lipid consisting of 40 amino acids. In addition, the yeast genome contains about 140 genes encoding RNA arranged at the long terminal of the chromosome; 40 genes encoding SnRNA interspersed with 16 chromosomes; and 275 tRNA genes belonging to 43 families are also widely distributed In the genome. Table 1 provides the general distribution of yeast genes on each chromosome.