Description:

Size: 100ul

Catalog no.: bs-1841R-A350

Price: 380 EUR

Product details

Gene ID Number

4000

Modification Site

None

Target Antigen

lamin A/C

Tested applications

IF(IHC-P)

French translation

anticorps

Clonality

Polyclonal

Modification

Unmodified

Concentration

1ug per 1ul

Excitation emission

343nm/442nm

Conjugated with

ALEXA FLUOR® 350

Crossreactivity

Human, Mouse, Rat

Clone

Polyclonal antibody

Recommended dilutions

IF(IHC-P)(1:50-200)

Purification

Purified by Protein A.

Conjugation

Alexa Fluor,ALEXA FLUOR 350

Category

Conjugated Primary Antibodies

Host Organism

Rabbit (Oryctolagus cuniculus)

Also known as

Anti-lamin A/C PAb ALEXA FLUOR 350

Specificity

This is a highly specific antibody against lamin A/C.

Long name

lamin A/C Polyclonal Antibody, ALEXA FLUOR 350 Conjugated

Cross-reactive species details

Due to limited amount of testing and knowledge, not every possible cross-reactivity is known.

Source

This antibody was obtained by immunization of the host with KLH conjugated synthetic peptide derived from human lamin A/C

Synonyms

FPL; FPLD; HGPS; IDC; Lamin A/C; LaminC; LDP1; LGMD1B; LMN 1; LMN C; PRO1; LMNA_HUMAN; Prelamin-A/C; Lamin-A/C; 70 kDa lamin; Renal carcinoma antigenNY-REN-32.

Storage conditions

Store this antibody in aqueous buffered solution containing 1% BSA, 50% glycerol and 0.09% sodium azide. Keep refrigerated at 2 to 8 degrees Celcius for up to one year.

Properties

For facs or microscopy Alexa 1 conjugate.Alexa Fluor 350 conjugates can be used in multi-color flow cytometry with FACS's equipped with a second red laser or red diode.If you buy Antibodies supplied by Bioss Primary Conjugated Antibodies. ALEXA FLUOR they should be stored frozen at - 24°C for long term storage and for short term at + 5°C.

Background of the antigen

Nuclear Envelope Marker An important part of the cell nucleus is formed by nuclear lamina. Nuclear lamins form a network of filaments at the nucleoplasmic site of the nuclear membrane. Two main subtypes of nuclear lamins can be distinguished, i.e. A-type lamins and B-type lamins. The A-type lamins comprise a set of three proteins arising from the same gene by alternative splicing, i.e. lamin A, lamin C and lamin Adel10, while the B-type lamins include two proteins arising from two distinct genes, i.e. lamin B1 and lamin B2. The nuclear lamins comprise a unique subclass of the intermediate filament protein family. They share a molecular domain organisation with the other intermediate filament proteins in that they are fibrous molecules that have an aminoterminal globular head, a central rod of a-helices and a carboxyterminal globular domain. Many biochemical and molecular features of lamins have been studied, but their functions remain still largely undetermined. One of the functions ascribed to the lamina is the maintenance of the structural integrity of the nucleus. Besides interactions with the nuclear membrane and other intermediate filaments, lamins interact with the nuclear chromatin. Eukaryotic chromatin is organised into loops, which are attached to the nuclear matrix. This organisation is thought to contribute to compaction of the chromatin and regulation of gene expression. Lamins, as part of the nuclear matrix, may be involved in these processes since chromatin binding sites have been detected in both A- and B-type lamins.