Recombinant Proteins

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C6ORF108 Human

Chromosome 6 Open Reading Frame 108 Human Recombinant

This product is a recombinant C6ORF108 protein produced in E. coli. It is a single, non-glycosylated polypeptide chain consisting of 194 amino acids (specifically, amino acids 1 to 174 of the native protein sequence). The protein has a molecular weight of 21.2 kDa. A 20-amino acid His-tag is fused to the N-terminus of the protein to facilitate purification, which is carried out using proprietary chromatographic techniques.
Shipped with Ice Packs
Cat. No.
BT9867
Source
Escherichia Coli.
Appearance
The product is a clear and colorless solution that has been sterilized by filtration.

C7ORF49 Human

Chromosome 7 Open Reading Frame 49 Human Recombinant

C7ORF49 Human Recombinant protein, produced in E. coli, is a single polypeptide chain comprising 180 amino acids. This includes the 157 amino acids of C7ORF49 itself and a 23 amino acid His-tag attached to its N-terminus. With a molecular weight of 19.2kDa, it undergoes purification using proprietary chromatographic methods.
Shipped with Ice Packs
Cat. No.
BT9955
Source
E.coli.
Appearance
A clear, sterile-filtered solution.

C9ORF103 Human

Chromosome 9 Open Reading Frame 103 Human Recombinant

Recombinant C9ORF103, expressed in E. coli, is a non-glycosylated polypeptide chain with a molecular weight of 23.1 kDa. This protein consists of 211 amino acids, including a 24 amino acid His-tag at the N-terminus (amino acids 1-187). Purification is achieved using proprietary chromatographic techniques.
Shipped with Ice Packs
Cat. No.
BT10030
Source
E.coli.
Appearance
Sterile, colorless solution.

C9ORF95 Human

Chromosome 9 Open Reading Frame 95 Human Recombinant

Recombinant human C9ORF95, expressed in E. coli, is a single, non-glycosylated polypeptide chain consisting of 222 amino acids (with amino acids 1-199 derived from C9ORF95) and possessing a molecular weight of 25.6 kDa. The protein includes a 23 amino acid His-tag at the N-terminus and is purified using proprietary chromatographic techniques.
Shipped with Ice Packs
Cat. No.
BT10113
Source
Escherichia Coli.
Appearance
A clear, colorless solution that has been sterilized by filtration.

SF20 Human

Chromosome 19 Open Reading Frame 10 Human Recombinant

Produced in E. coli, Recombinant Human SF20 is a single, non-glycosylated polypeptide chain. It consists of 162 amino acids (fragment 33-173), resulting in a molecular mass of 18 kDa. The protein, also known as C9orf10, is fused to a 20 amino acid His tag at its N-terminus and undergoes purification using proprietary chromatographic methods.
Shipped with Ice Packs
Cat. No.
BT10186
Source
Escherichia Coli.
Appearance
A clear solution that has been sterilized by filtration.

C19ORF80 Human

Chromosome 19 Open Reading Frame 80 Human Recombinant

Recombinant C19ORF80, produced in E. coli, is a single, non-glycosylated polypeptide chain encompassing amino acids 22-198, totaling 187 amino acids. It includes a 10 a.a N-terminal His tag and has a calculated molecular mass of 21.1 kDa.
Shipped with Ice Packs
Cat. No.
BT9532
Source
Escherichia Coli.
Appearance
White, lyophilized powder after filtration.

C19ORF80 Mouse

Chromosome 19 Open Reading Frame 80 Mouse Recombinant

Recombinant C19ORF80 Mouse, produced in E. coli, is a non-glycosylated polypeptide chain consisting of amino acids 16-198 (including a 10 a.a. N-terminal His tag). This single chain protein has a calculated molecular mass of 21.8 kDa.
Shipped with Ice Packs
Cat. No.
BT9622
Source
Escherichia Coli.
Appearance
White powder, lyophilized after filtration.

C14ORF129 Human

Chromosome 14 Open Reading Frame 129 Human Recombinant

C14ORF129 Human Recombinant is a single, non-glycosylated polypeptide chain with 159 amino acids (specifically, amino acids 1 to 139). It has a molecular weight of 17.8kDa. This recombinant protein is produced in E. Coli and is fused with a 20 amino acid His tag at its N-terminus. The purification process involves proprietary chromatographic techniques.
Shipped with Ice Packs
Cat. No.
BT9238
Source
Escherichia Coli.
Appearance
A clear solution that has been sterilized by filtration.

C16ORF53 Human

Chromosome 16 Open Reading Frame 53 Human Recombinant

Produced in E. coli, the non-glycosylated C16ORF53 polypeptide contains 274 amino acids (1-254 a.a.) with a molecular mass of 29.9 kDa. Note: SDS-PAGE analysis might show a higher molecular weight due to the 20 amino acid His-tag fused at the N-terminus. Purification is achieved using proprietary chromatographic techniques.
Shipped with Ice Packs
Cat. No.
BT9306
Source
Escherichia Coli.
Appearance
Sterile, colorless solution.

C17ORF103 Human

Chromosome 17 Open Reading Frame 103 Human Recombinant

Recombinant human C17ORF103, produced in E. coli, is a single, non-glycosylated polypeptide chain comprising 136 amino acids (residues 1-113). It has a molecular weight of 15.4 kDa. For purification purposes, C17ORF103 is fused to a 23 amino acid His-tag at the N-terminus and purified using proprietary chromatographic techniques.
Shipped with Ice Packs
Cat. No.
BT9383
Source
Escherichia Coli.
Appearance
A clear, colorless solution that has been sterilized by filtration.
Definition and Classification

An open reading frame (ORF) is a sequence of DNA that starts with a start codon (usually AUG) and ends with a stop codon (UAA, UAG, or UGA). It is a segment of DNA that can be transcribed into RNA and translated into a protein. ORFs are crucial for identifying potential protein-coding regions within a genome .

Biological Properties

Key Biological Properties: ORFs are essential for gene prediction and annotation. They are used to identify potential protein-coding genes within a DNA sequence .

Expression Patterns: ORFs can be found in various regions of the genome, including coding and non-coding regions. They are transcribed into mRNA, which is then translated into proteins by ribosomes .

Tissue Distribution: The expression of ORFs can vary across different tissues and developmental stages. Some ORFs are ubiquitously expressed, while others are tissue-specific .

Biological Functions

Primary Biological Functions: ORFs encode proteins that perform various functions within the cell, including enzymatic activities, structural roles, and regulatory functions .

Role in Immune Responses: Some ORFs encode proteins involved in immune responses, such as cytokines and receptors that recognize and respond to pathogens .

Pathogen Recognition: ORFs can encode proteins that recognize and bind to pathogen-associated molecular patterns (PAMPs), initiating immune responses .

Modes of Action

Mechanisms with Other Molecules and Cells: ORFs encode proteins that interact with other molecules and cells through various mechanisms, including binding to receptors, forming complexes, and participating in signaling pathways .

Binding Partners: Proteins encoded by ORFs can have specific binding partners, such as other proteins, nucleic acids, or small molecules, which are crucial for their function .

Downstream Signaling Cascades: ORF-encoded proteins can activate downstream signaling cascades, leading to various cellular responses, such as gene expression, cell proliferation, and apoptosis .

Regulatory Mechanisms

Transcriptional Regulation: The expression of ORFs is regulated at the transcriptional level by various factors, including transcription factors, enhancers, and silencers .

Post-Translational Modifications: ORF-encoded proteins can undergo post-translational modifications, such as phosphorylation, ubiquitination, and glycosylation, which can affect their stability, localization, and activity .

Applications

Biomedical Research: ORFs are used in biomedical research to study gene function, protein interactions, and disease mechanisms .

Diagnostic Tools: ORFs can be used as biomarkers for diagnosing diseases, such as cancer and genetic disorders .

Therapeutic Strategies: ORFs are targeted in therapeutic strategies, such as gene therapy and the development of small molecule inhibitors .

Role in the Life Cycle

Development: ORFs play a crucial role in development by encoding proteins that regulate cell differentiation, growth, and morphogenesis .

Aging: The expression and function of ORFs can change with aging, affecting cellular processes and contributing to age-related diseases .

Disease: Mutations or dysregulation of ORFs can lead to various diseases, including cancer, neurodegenerative disorders, and metabolic diseases .

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