Recombinant Proteins

TCL
p53
LBP
CEA
HLA
TTC
NPM
MAF
Bax
BID

TCL1A Human

T-cell Leukemia/Lymphoma 1A Human Recombinant

Recombinant human TCL1A, produced in E. coli, is a single, non-glycosylated polypeptide chain consisting of 114 amino acids (amino acids 1-114). It has a molecular weight of 13.4 kDa and is purified using proprietary chromatographic techniques.
Shipped with Ice Packs
Cat. No.
BT11102
Source
Escherichia Coli.
Appearance
A clear and colorless solution that has been sterilized by filtration.

TCL1B Human

T-cell Leukemia/Lymphoma 1B Human Recombinant

Recombinant human TCL1B protein was produced in E. coli. It is a single, non-glycosylated polypeptide chain consisting of 151 amino acids (1-128a.a) and has a molecular weight of 17.2 kDa. The TCL1B protein is fused to a 23 amino acid His-tag at the N-terminus and is purified using proprietary chromatographic techniques.
Shipped with Ice Packs
Cat. No.
BT11187
Source
Escherichia Coli.
Appearance
A clear, sterile-filtered solution.
Definition and Classification

TCL stands for Transaction Control Language. It is a subset of SQL (Structured Query Language) used to manage transactions within a database. TCL commands ensure data integrity by allowing you to control when changes to the database are saved permanently or rolled back. The primary TCL commands include COMMIT, ROLLBACK, and SAVEPOINT .

Biological Properties

TCL, in the context of biological sciences, does not have direct biological properties, expression patterns, or tissue distribution. However, if you are referring to Thin Layer Chromatography (TLC), it is a technique used to separate non-volatile mixtures. TLC is based on the principle that various constituents will have different solubilities and adsorption to the stationary and mobile phases .

Biological Functions

Thin Layer Chromatography (TLC) is primarily used for the separation, identification, and purification of components in a mixture. It plays a crucial role in analyzing biological samples, such as amino acids, proteins, and lipids, by separating them based on their affinity to the stationary and mobile phases .

Modes of Action

In TLC, the sample is applied on a plate coated with a thin layer of adsorbent material (stationary phase). A solvent or solvent mixture (mobile phase) is drawn up the plate via capillary action. Different analytes ascend the TLC plate at different rates, achieving separation based on their affinity to the stationary phase .

Regulatory Mechanisms

TLC does not have regulatory mechanisms in the biological sense. However, in the context of laboratory techniques, the quality and consistency of the stationary and mobile phases, as well as the environmental conditions, are critical for accurate results .

Applications

TLC has numerous applications in biomedical research, including:

  • Drug Analysis: Identifying and quantifying pharmaceutical compounds.
  • Biochemical Analysis: Separating and analyzing amino acids, proteins, and lipids.
  • Clinical Diagnostics: Detecting metabolic disorders by analyzing body fluids .
Role in the Life Cycle

TLC is used throughout various stages of research and development in the life sciences. From the initial stages of drug discovery and development to quality control and clinical diagnostics, TLC plays a vital role in ensuring the accuracy and reliability of analytical results .

© Copyright 2024 Thebiotek. All Rights Reserved.