Monitoring the Undifferentiated Stage of Stem Cells—the Pluripotency Markers

Human embryonic stem (ES) cells or induced pluripotent stem (iPS) cells promise to serve as an unlimited source for transplantation or tissue-specific differentiation. However, obtaining and maintaining stem cells are very difficult tasks for multiple reasons. For instance, most stem cell lines tend to spontaneously differentiate in culture, and even if the cells form stem cell-like colonies, they may be of a heterogeneous population.

To identify pluripotency of stem cells, expression of stem cell-specific marker genes (i.e. Oct-3/4, Sox2, Nanog, Rex-1) is monitored by RT-PCR. Alkaline phosphatase activity and methylation profiles of promoters of pluripotency-relevant genes are often analyzed as well. Compared to murine cells, it is noticeably more difficult to obtain human iPSCs, of which stem cell-like colonies sometimes turn out not to be pluripotent cells. We highly recommend testing iPSCs, especially human iPSCs, with antibodies against stage-specific embryonic antigens such as SSEA-3, SSEA-4, TRA-1-60, and TRA-1-81.

However, all of these methods require cell destruction or fixation for analysis, therefore, are inconvenient and costly. Furthermore, many studies using ES or iPS cells involve differentiation of stem cells into different lineages, a method for observing live cells to know their undifferentiation/differentiation stages would be very helpful. There have been a number of publications using murine Oct-4, Nanog, and Rex-1 promoter driven fluorescent proteins as markers for pluripotency tests [1-3]. Allele Biotech provides, under its iPS product line, packaged and validated lentiviral particles that would insert these 3 promoter-FP reporters into the stem cells. Although currently these promoters are of mouse sequences, their use in human stem cells have been reported.

New product of the week 01-25-10 to 01-31-10:

All-In-One-Vector: Human OSKM Lentiviral Paticles, with Oct-4, Sox-2, Klf, and c-Myc all expressed from a single virus, ready-to-use.

Promotion of the week:

human iPS cell detection primer set, the same as the landmark Yamanaka paper [4] on creating human iPS for the first time.

1. Da Yong WU, Zhen YAO (2005). Isolation and characterization of the murine Nanog gene promoter. Cell Research, 15 (5): 317–324.
2. Rachel Eiges, Maya Schuldiner..et.al (2001). Establishment of human embryonic stem cell?transfected clones carrying a marker for undifferentiated cell. Current Biology 11: 514–518.
3. Guangjin Pan, Jun Li, Yali Zhou, Hui Zheng, and Duanqing pei (2006). A negative feedback loop of transcription factors that control stem cell pluripotency and self?renewal. ASEB Journal 20: E1094? E1102
4. Takahashi et al, Induction of Pluripotent Stem Cell from Adult Human Fibroblasts by Defined Factors (2007). Cell 131, 861-872

Tags: differentiation, fluorescent protein, iPS, iPS lentivirus, iPSC, iPSCs, lentivirus, pluripotency reporter, promoter, promoter-FP, stem cells, undifferentiation stage

Commonly Known Facts About Viral Packaging -That Might Not Be Correct…

Packaging lentiviruses or retroviruses is not a routine procedure that every biology lab performs even if there is need to use it. A viral packaging protocol normally begins with preparation of purified transfer plasmid DNA, a miniprep should be enough for a few transfections. The virus backbone plasmid is either co-transfected into commonly used cells with helper plasmids that provide the essential proteins required for particle packaging, or transfected into established helper cell lines that express the required proteins from integrated transgenes. After incubation of packaging cells for a couple of days, viruses are collected and tittered. Titer determination is somewhat tricky for the inexperienced. Using a control virus expressing a fluorescent protein can make this step convenient.

Commonly known facts:

1) Lentiviruses are packaged at a titer of 10^6 IU/ml without concentrating steps.

This needs update since with more advanced technologies lentiviruses can be packaged routinely at 10^8 IU/ml. With further concentrating, the titer can be easily above 10^11 IU/ml. Retroviruses can be packaged to similar titers as well.

2) Using packaging cell lines gives the highest possible titer

While packaging cell lines (such as Allele’s popular Phoenix Eco and Ampho cells for retrovirus packaging) provides maybe the most convenient method for packaging, the yield will not reach the highest potential. Packaging cell lines may also lose their capability for packaging after continued culturing, requiring periodic selection with antibiotics and functional tests, as we do here at Allele.

3) Retroviruses are always collected in one shot after transfection into packaging cells

If the transfer vector has oriP/EBNA1 episomal maintenance system, such as some of the Phoenix vectors Allele offers, the plasmids may continue to express for up to 30 days. With puromycin selection, the titer of retrovirus produced from Eco or Ampho cells can reach 10^7 IU/ml.

This week’s promotion (102509-103109): 10% off across the board of Allele Biotech’s custom services, for an example, check out our world-leading baculovirus protein expression.

New Product/Service of the Week: Introduction of Custom Viral Packaging Service. Routine titer of 10^8 IU/ml, as high as 10^10 IU/ml, option to include cloning. Signature service ABP-CS-MERV002 provides more than 200 million particles at $7/million particles. These are game-changing prices for the viral packaging service market based on superior technologies!

Tags: baculovirus, co-transfection, custom service, iPS lentivirus, iPS retrovirus, lentivirus, packaging cells, protein expression, retrovirus, viral packaging, viral particles, viral vectors, virus titers