LAMC1 Knockout cell line(HCT 116)

Catalog Number: KO00624

Specifications KO Solutions KO Cell Line Workflow Handling procedures Downloads Related products

Specifications

Product Information
Product Name	LAMC1 Knockout cell line(HCT 116)
specification	1*10^6
Storage and transportation	Dry ice preservation/T25 live cell transportation.
Cell morphology	Epithelioid, adherent cell
Passage ratio	1:2~1:4
species	Human
Gene	LAMC1
Gene ID	3915
Build method	Electric rotation method / virus method
Mycoplasma testing	Negative
Cultivation system	90%McCOYs 5A+10% FBS
Parental Cell Line	HCT 116
Quality Control	Genotype: LAMC1 Knockout cell line(HCT 116) >95% viability before freezing. All cells were tested and found to be free of bacterial, viruses,mycoplasma and other toxins.

Gene Information
Gene Official Full Name	laminin subunit gamma 1provided by HGNC
Also known as	LAMB2
Gene Description	Laminins, a family of extracellular matrix glycoproteins, are the major noncollagenous constituent of basement membranes. They have been implicated in a wide variety of biological processes including cell adhesion, differentiation, migration, signaling, neurite outgrowth and metastasis. Laminins, composed of 3 non identical chains: laminin alpha, beta and gamma (formerly A, B1, and B2, respectively), have a cruciform structure consisting of 3 short arms, each formed by a different chain, and a long arm composed of all 3 chains. Each laminin chain is a multidomain protein encoded by a distinct gene. Several isoforms of each chain have been described. Different alpha, beta and gamma chain isomers combine to give rise to different heterotrimeric laminin isoforms which are designated by Arabic numerals in the order of their discovery, i.e. alpha1beta1gamma1 heterotrimer is laminin 1. The biological functions of the different chains and trimer molecules are largely unknown, but some of the chains have been shown to differ with respect to their tissue distribution, presumably reflecting diverse functions in vivo. This gene encodes the gamma chain isoform laminin, gamma 1. The gamma 1 chain, formerly thought to be a beta chain, contains structural domains similar to beta chains, however, lacks the short alpha region separating domains I and II. The structural organization of this gene also suggested that it had diverged considerably from the beta chain genes. Embryos of transgenic mice in which both alleles of the gamma 1 chain gene were inactivated by homologous recombination, lacked basement membranes, indicating that laminin, gamma 1 chain is necessary for laminin heterotrimer assembly. It has been inferred by analogy with the strikingly similar 3' UTR sequence in mouse laminin gamma 1 cDNA, that multiple polyadenylation sites are utilized in human to generate the 2 different sized mRNAs (5.5 and 7.5 kb) seen on Northern analysis. [provided by RefSeq, Aug 2011]
Expression	Broad expression in placenta (RPKM 116.1), fat (RPKM 63.0) and 19 other tissues See more

KO Solutions

We develop gene knockout solutions tailored to customer requirements and the condition of the target gene.

Editing Tools

Cas9 Protein

Cas9 mRNA sgRNA

Cas9 Plasmid

Cas9 Virus

A – Exon KO

gRNAs are designed in the introns flanking the exon, targeting non-multiple-of-3 base deletions in the exon, resulting in frameshift mutations.

B - Frameshift KO

gRNAs are designed within the exon, creating non-multiple-of-3 base deletions to induce frameshift mutations.

C - Complete KO

The entire gene coding sequence is deleted, achieving large-scale knockout effects.

KO Cell Line Workflow

KO Strategy Design

CRISPR Plasmid/Lentiviral Vector Construction

Lentiviral Packaging

Cell Transfection/Lentiviral Infection

Drug Selection

Cell Cryopreservation

Quality Control

Sequencing Validation

Monoclonal Cell Line Generation

Pool Efficiency Validation

Handling procedures

Cell Thawing

Pre-warm complete culture medium in a 37°C water bath.
Thaw the cryovial in a 37°C water bath for 1–2 minutes.
Transfer the cryovial to a biosafety cabinet (BSC) and wipe the surface with 70% ethanol.
Loosen the cap and gently transfer the cell suspension into a sterile centrifuge tube containing 9 mL of complete medium.
Centrifuge at 125 × g for 5–7 min at room temperature (RT), then discard the supernatant.
Resuspend the cell pellet in 5 mL of complete medium and transfer the suspension into a T25 flask.
Incubate the cells at 37°C in a 5% CO₂ incubator.
Recommended subculturing ratio: 1:2 to 1:3, reaching confluency in 2–3 days.

Cell Passaging

When cell confluence reaches 80–90%, proceed with passaging.
Pre-warm complete medium, PBS, and trypsin (0.25% Trypsin-EDTA, Gibco 25200-056) in a 37°C water bath. Once near 37°C, spray the bottles with 75% ethanol and place them in the BSC.
Retrieve the culture flask from the incubator, spray with 75% ethanol, and transfer it to the BSC.
To avoid dislodging cells, gently rinse the monolayer with PBS along the upper wall of the flask. Discard the PBS after washing (use 2 mL for T25 flasks).
Add an appropriate volume of trypsin (1.5 mL for T75, 0.5 mL for T25) and gently tilt the flask to ensure full coverage. Adjust the volume as needed. After 1–2 min, when most cells detach, neutralize digestion by adding an equal volume of complete medium. Gently pipette with a 5 mL serological pipette to ensure complete detachment.
Transfer the cell suspension to a 15 mL centrifuge tube and spin at 300 × g for 5 min. Discard the supernatant.
Resuspend the pellet in 5 mL of complete medium, adjust the seeding ratio as required, and replenish the flask with fresh medium (13–15 mL for T75, 5 mL for T25). Add 1% penicillin-streptomycin (dual antibiotic).
Tighten the cap, gently swirl to mix, and place the flask in a 37°C, 5% CO₂ incubator.

Cell Cryopreservation

Prepare cryopreservation medium in advance and pre-chill.
Ensure cells meet freezing criteria: healthy morphology, late-log phase growth, and absence of contamination or senescence (verify under a microscope).
Digest and centrifuge the cells (refer to the passaging protocol).
Resuspend the cell pellet in cryopreservation medium (1 mL per vial), mix thoroughly, and aliquot into cryovials.
Place the vials in a freezing container and store at −80°C overnight.
For long-term storage, transfer the cryovials to a liquid nitrogen tank.

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