Introduction
Prolactin is a pleiotropic hormone whose numerous actions are associated with reproduction, growth and development, water and electrolyte balance, metabolism, behavior and immunoregulation [1]. The prolactin-dependent rat Nb2 lymphoma (Nb2-11C) is widely used as a model in which to study signal transduction and transcriptional mechanisms that underlie prolactin-stimulated mitogenesis (reviewed in [1,2,3]). Deprivation of lactogen induces a block in the early G1 phase of the Nb2 cell cycle [4]. The addition of physiological concentrations of prolactin to synchronized G0/G1-arrested cultures reinitiates cell-cycle progression [5], which is characterized by the induction of growth-related genes such as those for c-Myc, ß-actin and ornithine decarboxylase (ODC) and
We have characterized known and unknown transcripts identified by these five techniques, adding information relative to their expression peak or expression variations during Nb2 cell proliferation. Whenever possible, prolactin-induced transcripts were compared with those in other eukaryotic models of cell-cycle progression such as
Results
Application of the different screening techniques to Nb2 cells
When deprived of lactogen, 80-85% of an Nb2 cell culture is synchronized in growth arrest [5] (Figure
Most of the potential positive clones isolated by differential display, RDA, SSH and screening of rat brain organized library were analyzed by northern blot to eliminate false positives and to evaluate variations in the expression of each clone during the Nb2 proliferative response. The remaining cDNA clones were tested using reverse northern blot to rapidly eliminate false-positive cDNAs. Briefly, PCR products corresponding to potential positive clones were screened by hybridization with complex probes generated from the populations tested. This step was necessary because of the high rate of false-positive clones generated by the earlier protocols used for differential display. The method has since been improved and may now have a better readout. Sequencing of these clones enabled us to identify known transcripts and to determine which ones were of unknown genes.
Together, the different techniques enabled the isolation of about 70 known or unknown differentially expressed transcripts potentially involved in the resumption of cell proliferation by quiescent cells. A summary of the data is presented in Table
Cell-cycle analysis of synchronized Nb2 cells stimulated by prolactin
Cell-cycle analysis of synchronized Nb2 cells stimulated by prolactin. Nb2 cells were serum deprived for 24 hours, then incubated with no PRL or PRL at 20 ng/ml before cells were collected for analysis. DNA content (FL2-A)
Expression profiles of various known and unknown transcripts during Nb2 cell cycle progression
Expression profiles of various known and unknown transcripts during Nb2 cell cycle progression. Samples of total RNA (10 µg) were loaded per lane and blots were hybridized with the indicated cDNA probes. Ethidium bromide staining (EtBr) of the gels is shown as a control (18S and 28S rRNA). (a) Cdc21 homolog; (b) Ant-2; (c) CRM-1; (d) CD45; (e) unknown DD3; (f) unknown 4-16; (g) unknown 4-15; (h) unknown 6-4.
Putative signaling molecules potentially involved in Nb2 cell survival and/or cell-cycle progression
The list of differentially expressed transcripts has been completed with Nb2 cell transcripts described in previous reports (Table
Functional classification of cell-cycle-regulated transcripts
We identified 70 differentially expressed genes in proliferating Nb2 cells. Although this number is not negligible, it is of course not exhaustive, as the number of genes involved in cell-cycle modifications could be as high as several hundred. However, estimations of the number of genes modulated using other proliferation and cell-cycle models, such as yeast [24,25,26] or human fibroblasts [27,28], are equally limited. We compared these different models, adding new information generated from large-scale differential screening techniques (microarrays and DNA chips). On the basis of these analyses, approximately 7% of transcripts from yeast (416 out of 6,220) and 6% from normal human fibroblasts (517 out of 8,600) display cell-cycle-dependent fluctuations. All the yeast cell-cycle-regulated transcripts are not, however, regulated in vertebrates, and
These transcripts were classified into 10 different functional categories as shown in Table
These functional categories agree with previous observations concerning cell-cycle-regulated transcripts in various eukaryotic models. Indeed, cell-cycle-dependent mRNA fluctuations have been observed for genes involved in many cellular processes, including control of mRNA transcription [29], responsiveness to external stimuli [30] and subcellular localization of proteins [31]. Genetic studies have revealed that the activity of cell-cycle regulatory proteins is required for normal DNA repair [32], meiosis [33] and multicellular development [34,35]. These observations suggest that, in eukaryotic cells, diverse biological events depend on maintenance of this periodicity.
Expression abnormalities
The loss of appropriate cell-cycle regulation leads to genomic instability [36] and is believed to have a role in the etiology of both hereditary and spontaneous cancers [37,38,39,40]. In Nb2-11C cells, several growth-related genes that display abnormalities in their expression patterns were observed. These abnormalities may be the cause or the consequence of the tumor phenotype of Nb2 cells.
Using the candidate gene approach (Figure
Analysis of candidate gene expression
Analysis of candidate gene expression. (a) General principles. Messenger RNAs from the different cell populations (cells A and B) are reverse transcribed. Multiplex PCR is then performed using specific primer pairs to amplify the cDNAs of interest. The resulting mixture of PCR products is radiolabeled and these complex probes are used to hybridize identical membranes spotted with the candidate gene cDNA targets. After autoradiography, the intensities of the hybridization signals are compared and quantified. Arrows indicate the positions of differentially expressed genes. The absence of hybridization (open circles) indicates that the candidate gene is not expressed. (b) Efficiency of the technique and examples of differentially expressed genes. The expression of different candidate genes was compared in either unsynchronized (UN), growth-arrested (GA), G1 phase (G1), G1/S transition (G1/S) or G2 phase (G2) cultures of Nb2 cells. The efficiency of the technique was controlled using equivalent amounts of rabbit a and ß globin cDNAs, which were included on the nylon membranes along with the candidate gene targets. The two globin cDNAs were added in different amounts (50 or 150 ng) to each cDNA population before co-amplification. For each population tested, filters were hybridized with both globin probes, but only representative hybridization signals are shown, for either a (Panel A) or ß (Panel B) globin. Numbers 1 and 3 represent the relative amount of the control rabbit globin cDNAs added, and are reflected in the differences in the intensity of the hybridization signals. Thus, a threefold difference in the quantity of a particular transcript in the initial population generates a clear difference in the intensity of the corresponding hybridization signals. Rows C, D, E and F are examples of the results obtained with ganglioside synthase GD3, EGR-1, FAK p125 and Stat3, respectively. Except for Stat3, which is not differentially expressed in probes UN, GA, G1, G1/S and G2, the three other genes showed a clear differential expression. (c) Northern blot analysis showing the constitutive expression of EGR-1 during Nb2 cell-cycle progression. Growth-arrested Nb2 cells were stimulated with ovine prolactin and collected after various periods of stimulation corresponding to different stages of the cell cycle (G1, G1/S and G2). The expression of EGR-1 was evaluated by northern blot using 10 µg of total RNA from the various times following prolactin stimulation. Ethidium bromide (EtBr) staining of the gel is shown as a control (18S and 28S rRNA).
Schematic representation of rat candidate genes on a nylon filter
Schematic representation of rat candidate genes on a nylon filter. Squares with names and accession numbers represent the places where the cDNAs were spotted. The solid gray boxes correspond to the controls (rabbit a and ß globin). The boxes enclosed in a thick black square represent differentially expressed genes in Nb2 cells; the boxes enclosed in a thin black square represent genes that are repressed, but not differentially in Nb2 cells; and those enclosed in an oval correspond to expression abnormalities in Nb2 cells.
Differentially expressed transcripts found in Nb2 cells during cell-cycle progression using five different screening techniques
Identity
Accession number
Expression variations
Differential display
Unknown DD3
No EST
Three transcripts (2, 2.8, 3.7 kb)
expressed in G1 and G1/S,
(>4-fold induction)
Representational difference analysis: G1/S-GA
ATP synthase ß subunit
M19044
Induced in G1/S, G2 (2-fold induction)
Aldehyde dehydrogenase
U79118
Induced in late G1 (2-fold induction)
Enolase a1
NM012554
Induced in late G1 (2-fold induction)
Dynein heavy chain
D13896
Induced in G1, G1/S (3-fold induction)
TCP-1 e
D43950(h)
Induced in G1/S, G2 (3-fold induction)
aCOP (COPA)
U24105
Induced in late G1 (2-fold induction)
Cdc21 homolog
D26089 (m)
Peaks in G1/S (>8-fold induction)
Ribosomal protein L26
A1716351
Induced in late G1 (2-fold induction)
Itm1
A1956728 (h)
Induced in G1/S (2-fold induction)
Unknown T22
A1053031 (h)
6 kb, 2-fold induction in G1/S
Unknown T34
A1235326
2 kb, 2-fold induction in G1/S
Subtractive suppressive hybridization: G1-GA
Galectin-8
U09824
Induced in G1 (2-fold induction)
Hsp86
X16857
Induced in late G1 (>3-fold induction)
TCP-1 ?
AA900460
Induced in late G1 (2-fold induction)
Ribosomal protein L13A
X68282
Induced in late G1 (2-fold induction)
Ribosomal protein L12
AA900142
Induced in late G1 (2-fold induction)
Ribosomal protein L3
A1687295
Induced in G1 (2-fold induction)
Y00441
Induced in G1 (2-fold induction)
ß2-microglobulin
D12771
Induced from late G1 to G2 (>5 fold induction)
Adenine nucleotide translocator ANT-2
NM011342 (m)
Induced in G1 (2-fold induction)
Sec-22
NM012562
Induced in G1 (2-fold induction)
L-fucosidase
U91538
Induced in G1/S (>3-fold induction)
CRM-1 homolog/exportin 1
X81839
Induced in G1/S (>3-fold induction)
Ubiquitin/ribosomal protein S27a
A47416
Induced in G1/S (>3-fold induction)
Ubiquitin/ribosomal protein S30 (FAU)
AF195142 (m)
3-fold induction in G1 (1.5 kb)
Unknown 4-2 (mouse selenoprotein R mRNA)
H35219
2-fold induction in G1/S (2 and 4 kb)
Unknown 4-4 (human KIAA0081)
No EST
2-fold induction in G1 (1 kb)
Unknown 4-11
AU035826
4-fold induction in G1 (1 and 1.5 kb)
Unknown 4-15
AF046001
4-fold induction in G1 (2.5 kb)
Unknown 4-16 (human ZNF207 or mouse Zep)
No EST
3-fold induction in G1 (1.5 kb)
Unknown 4-20
AW435432
2-fold induction in G1
Unknown 4-27 (new ribosomal protein L15 type)
A1121996 (m)
2-fold induction in G1
Unknown 4-49
AW246248 (h)
2-fold induction in G1
Unknown 4-58 (SH3, Rab GAP, TBC domain)
No EST
2-fold induction in G1
Unknown 4-59
Subtractive suppressive hybridization: GA-G1
Spermidine/spermine N-acetyl transferase (SSAT)
AA955996
Repressed transiently in G1
Leukocyte common antigen (alternative splicing) CD45
Y00065
Switch between two transcripts (one
repressed, the other induced in G1)
ZFX
X75171
Repressed transiently in G1
Ribosomal protein S8
AA874997
Repressed transiently in G1
Ribosomal protein S13
L01123
Repressed transiently in G1
Unknown 6-2
No EST
Repressed transiently in G1
Unknown 6-3 (hypothetical protein expressed in thymocytes)
AJ237585 (m)
Repressed transiently in G1
Unknown 6-4
No EST
Repressed in G1
Unknown 6-9
No EST
Repressed transiently in G1
Unknown 6-10
No EST
Repressed transiently in G1
Unknown 6-12 (human protein KIAA0710)
AB014610 (h)
Repressed transiently in G1
Unknown 6-45 (homolog to mouse PARP-2)
NM009632 (m)
Repressed transiently in G1
Differential screening of a rat organized library: G2-GA
Prothymosin a
M86564
Induced in G2
Cyclophilin
M19533
Induced in G2
ATP synthase ß subunit
M19044
Induced in G1/S and G2
Tubulin a2
AA686718
Induced in G1/S and G2
GaPDH
X02231
Induced in G2
Phosphoglycerate kinase
M31788
Induced in G1/S and G2
MRG1 related protein
U65093
Induced in G1/S and G2
Unknown BO1
No EST
Induced in G2
Analysis of weakly expressed candidate genes: UN, A, GI, G1/S, G2
Name
Accession number
Fold induction
Kinetics
Ganglioside synthase (GD3)
D84068
> 4
P13 kinase
D64045
> 3
Phospholipase C?1
M34667
> 3
Bax
S76511
> 2
P53
X13058
> 2
FAKp125
AF020777
> 3
14-3-3 e
M84416
> 2
14-3-3 ?
D17445
> 2
Vitamin D3 receptor
J09838
3
Glycine transporter
M88595
3
Thromboxane A2 receptor
D32080
2
Phosphatidylinositol transfer protein
D17445
2
RexB/NSP
U17604
> 2
Glucocorticoid receptor
M14053
2
Ga3PDH
J04147
2
Zif268 = EGR1
U75398
2
Nb2 cells: UN, unsynchronized; GA, growth arrested; G1, G1 phase; G1/S, G1/S transition; G2, G2 phase. PC12, rat pheochromocytoma PC12 cells. 18S and 28 S, ribosomal RNA. Whenever possible, rat accession numbers (GenBank) are written in the second column. When this sequence is not in known for the rat, (h) or (m) indicates that the accession number corresponds, respectively, to a human and a mouse cDNA homologous to those of the rat. `No EST' means that our rat sequence does not correspond to any previously described EST in mammals. For some of the unknown cDNAs, an estimation of the size of the corresponding transcript(s) as well as the fold induction is given in the right column `Expression variations', and for weakly expressed candidate genes, the expression kinetics are shown.
Functional classification of cell-cycle-regulated transcripts found in Nb2 cells
Category
Transcript
Cell cycle: cyclins and cell-cycle regulators
Transcripts that have a cell-cycle-modulated homolog in yeast
Cyclin E1 [78], peaks in G1
EGR-1, immediate-early gene (constitutive expression in Nb2 cells)
Cdc5-like protein [79], peaks in M
Cdk2, Cdk5 [78], peak in G1
Cell-cycle-modulated transcripts with a yeast homolog (not modulated)
Cyclin B1, peaks in G2/M
Cell-cycle-modulated transcripts with no yeast homolog
Cyclin B2, peaks in G2
Cyclin D2 [8], peaks in G1
Cyclin D3 [8], peaks in G1
Nucleotide metabolism, DNA replication and repair
Cdc21 homolog
Spermidine/spermine N-acetyl transferase (SSAT)
Ornithine decarboxylase (ODC) [80]
Prothymosin a
PARP-2 (Unknown 6-45)
Chromatin structure
Histones H2A, H2B, peak in S in mammals and in yeast
Cytoskeleton
Myosin heavy chain
Tubulin a, ß
ß-actin [6]
Clone 15 = rNUDC [81]
FAK p125
Cell-surface antigens, adhesion molecules and signaling molecules
(involved in apoptosis, survival and/or proliferation)
Growth factor
FGF-2 [82]
Surface molecules
Prolactin receptor Nb2 form [16]
T-cell receptor ? chain [17]
T-cell receptor a chain [17]
GnRH receptor [83]
Glucocorticoid receptor
Galectin-8
Leukocyte membrane glycoprotein, CD45
Vitamin D3 receptor
Thromboxane A2 receptor
ß2-microglobulin
Cytoplasmic and/or nuclear signaling molecules
p38 Map kinase [21]
Pim-1 [9]
Gfi-1 [10]
Stathmin [84]
P13 kinase p110 a
Phospholipase C?1
14-3-3 ? and e
Bax
p53
RexB/NSP
Phosphatidylinositol transfer protein
a 4 phosphoprotein [79]
Transcription factors
IRF-1 [7]
c-Myc [18]
c-Fos (not in Nb2 cells [18])
MRG1-related protein
E2F-1 [78]
Zfx
Heat shock, stress response and chaperones
Cyclophilin (B)
TCP-1 e and ?
Hsp70 (not expressed in Nb2 cells)
Hsp70-like = Nb29 [41]
Hsp27
Hsp86
ß-actin
a2-tubulin
Rdnuc (Golgi-associated protein) [11]
Myosin heavy chain
Focal adhesion kinase (FAK)
Metabolism (energy)
Phosphoglycerate kinase
Enolase a
Aldehyde dehydrogenase
ATP synthase ß subunit
Protein and RNA synthesis, modifications and degradation
Ribosomal proteins
L3, L12, L13A, new ribosomal protein L15 type (unknown 4-27)
S8, S13
Glycosylation factor
Itm1
Elongation factor
EF-2 [77]
Inter-compartment transport and trafficking
CRM-1 = exportin 1
Sec-22
Glycine transporter
Unknown 4-58 (SH3, Rab GAP, TBC domain: putative nuclear pore protein)
Unknown function(s)
FGF-responsive Non/p54nrb
Unknowns T22, T34, 4-2, 4-4, 4-11, 4-15, 4-20, 4-49, 4-59, BO1
Unknowns 6-2, 6-3, 6-4, 6-9, 6-10, 6-12
Discussion
New putative signaling molecules in Nb2 cells
In this study we have identified new regulated genes encoding potential signaling molecules. Genes encoding proteins involved in cell survival, apoptosis, proliferation and/or cell-cycle progression may or may not have cell-cycle-dependent expression. Most of these proteins (listed in Tables
In our experiments, for example, PI 3-kinase, PLC?1 and ganglioside synthase GD3 share identical expression profiles, characterized by lower expression in unsynchronized than in synchronized Nb2 cells. This indicates that they may share similar regulation mechanisms. In high-density Nb2 cell cultures [48], secreted growth factors maybe involved in this negative regulation. PI 3-kinase and/or PLC?1 have been implicated in cell-cycle progression, proliferation, survival, transformation and apoptosis in different cellular models [49,50,51,52]. Thus, ganglioside synthase may also take part in similar processes in immune cells. Indeed, ganglioside synthase GD3 is highly expressed in various human cancer cell lines, is upregulated in activated T lymphocytes [53], and has been implicated in Fas-mediated apoptosis [23]. It may therefore be of interest to determine whether prolactin is able to activate, directly or indirectly, the activity of GD3 and the Fas signaling pathways.
Expression profiles of genes for Bax, p53, 14-3-3 e and FAK are characterized by increased mRNA expression during the G1, G1/S and G2 phases in comparison to the growth-arrested or unsynchronized Nb2 cells (Table
It is not known at present whether these expression profiles are common to all dividing mammalian cells or only to a particular subclass of immune-system cells. Alternatively, these profiles could be the consequence of the genetic abnormalities displayed by Nb2 cells. It is of interest that the expression of the p38 MAP kinase gene is modulated in Nb2 cells [21] but not in normal human fibroblasts [27,28], suggesting that this regulation is specific to the T-cell lineage. Different arguments exist in favor of the existence of cross-talk between the JAK/STAT and p38 MAP kinase pathways, at both the translational and transcriptional levels. As the expression of ganglioside synthase GD3 is restricted to the brain and the hematopoietic lineage, the regulation of the transcript and the involvement of the protein in the regulation of survival and apoptosis may also be shared by these tissues. In contrast, the cell-cycle-dependent expression of Ant-2, observed in both Nb2 cells (our results) and human fibroblasts [27,28], suggests that this feature is common to all dividing mammalian cells. These speculations require further experimentation at the protein level for confirmation.
Expression abnormalities
We report for the first time, to our knowledge, the constitutive expression of the transcription factor EGR-1 in synchronized proliferating cells. EGR-1 has a role in differentiation and development, in normal growth and in virus-induced growth and immortalization (reviewed in [58]). Many of these effects may be related to complex cooperative and competitive mechanisms between the three transcription factors Sp1, EGR-1 and Wt1, which often have overlapping binding sites in target promoters.
Several arguments suggest that EGR-1 may act as a tumor suppressor [59,60,61], and that its anti-oncogenic function could be due to the transcriptional induction of the gene for transforming growth factor ß1 (TGFß1), which suppresses growth by an autocrine mechanism in the late G1 phase of the cell cycle [62,63]. Exogenous TGFß inhibits Nb2 cell growth [64], suggesting that these cells are still sensitive to the anti-proliferative action of TGFß, but are unable to synthesize or activate TGFß on their own, despite their constitutive EGR-1 expression. It is possible that, in Nb2 cells, the anti-proliferative effect induced by the constitutive expression of EGR-1 is suppressed by other abnormalities such as a deficiency in the production of active TGFß.
Other studies, however, argue in favor of the existence of anti-apoptotic and/or pro-proliferative properties of EGR-1 [65,66,67,68]. In this context, the constitutive expression of EGR-1 in Nb2 cells suggests that this transcription factor may have both anti- and pro-proliferative effects, as previously described for other proteins such as p53 [69]. These dual and antagonistic functions may constitute a protective mechanism against tumor formation. In this model, three oncogenic abnormalities would have to occur in order to generate continuous tumor growth: immortalization; activation of all the transduction pathways required for proliferation; and suppression of all the anti-proliferative and apoptotic properties resulting from proto/anti-oncogene modifications.
Further studies are required to confirm the integrity of the EGR-1 protein and its constitutive expression in Nb2 cells and to understand the relationships between the EGR-1 target genes and their signaling pathways.
Comparison of various differential screening techniques
We have compared the advantages and drawbacks of four differential screening techniques. Of the four approaches, differential display analysis presents several advantages: it is easy, rapid, does not require large amounts of biological material, and it allows the comparison of multiple transcriptomes in a single experiment. The occurrence of false-positive clones is, however, quite high. In our experimental conditions, we isolated 20 potential positive cDNAs; only two, however, presented a relatively distinct cell-cycle-modulated expression profile. The problem with this technique lies in the low reproducibility of the PCR reaction and the occurrence of non-differential PCR products, which are recovered together with differentially expressed transcripts from the acrylamide gel. Several methods (such as reverse northern blots) have been proposed to circumvent this problem, albeit with rather limited success. Another disadvantage is that the identification of cDNA clones may be difficult if the model system studied has not previously been used in an extended EST sequencing program.
RDA and SSH are based on the same principle. These techniques are easy to use and enable the rapid generation of RDA or SSH subtractive libraries. The proportion of false-positive cDNAs can be less than 10% (our data), but if the differences between the two libraries are discrete, this number is increased. RDA or SSH cDNA clones correspond to sequences positioned in the middle portions of transcripts (generally coding regions), and the sequencing of each cDNA clone enables their identification independently of the model used. These techniques have two principal disadvantages: only two different transcriptomes can be compared in one experiment, and these approaches are far from being exhaustive. Although they should facilitate the detection of low-level transcripts, this is often not the case, as non-optimal conditions appear preferentially to select cDNAs corresponding to highly expressed transcripts.
The screening of an organized library can be compared with the use of DNA arrays, and the detection of a wide range of differential transcripts. This approach theoretically allows the screening of transcripts corresponding to unknown genes. False-positive cDNAs are relatively rare (10-20%) if the amount of DNA fixed on the high-density nylon filters is strictly controlled. The detection threshold for these techniques, however, does not allow the detection of weakly expressed differential transcripts and remains a major limitation.
The principle of the analysis of weakly expressed candidate genes is derived from that of macroarrays. In that case, the detection threshold is increased by a step of moderate PCR amplification for each candidate gene in the complex probes, but allows only a semi-quantitative detection of differentially expressed candidate genes. Internal controls are included to monitor the efficiency of the technique.
Cell-cycle-regulated transcripts in mammals
To facilitate the comparative analysis of cell-cycle-regulated transcripts, we classified them into ten different functional categories (Table
The current functional classification is too restrictive and does not take into account the interactions between these functional categories. For example, the regulation of proto-oncogene and cytokine mRNAs and proteins is particularly complex. The regulatory processes involved include transcriptional control, nuclear export and import of transcripts and proteins, translation, heat-shock pathways (Hsc70-Hsp70), and the ubiquitin- and proteasome-mediated degradation of mRNA and proteins [71]. Interestingly, transcripts of many proteins involved in these processes (such as Hsp proteins, translation factors, and CRM-1) were found to be induced by prolactin in Nb2 cells in this study, as well as in other models. Moreover, the abnormal heat-shock response described in Nb2 cells may perturb this regulation and have important consequences for tumor progression.
Comparison of cell-cycle regulated transcripts in yeast and higher eukaryotes
Data are still lacking for an extensive comparison of cell-cycle-modulated transcripts in unicellular (yeast) and multicellular organisms (essentially mammals) and for deduction of evolutionarily conserved features. Several conclusions can be drawn, however. In almost all the functional subclasses detailed in Table
There are numerous cellular and physiological differences between yeast and multicellular organisms, and some of the molecular divergences observed may reflect these differences. In unicellular organisms the growth priorities are to proliferate as long as enough nutrients are available. In contrast, in multicellular organisms the integrity of the organism is paramount, and individual cell behavior is highly controlled. Therefore proliferation is basically prohibited, and occurs in a cell lineage only if the environment sends the appropriate combination of signals to unlock all the growth-inhibition mechanisms. Despite these differences, cell-cycle checkpoints located just before and at the end of mitosis are essential and similar in all organisms. These two controls ensure that all the DNA has been correctly replicated before the cell enters mitosis and that the condensed chromosomes are properly aligned on the division spindle before anaphase. Thus, all proteins potentially involved in such controls may be regulated similarly from yeasts to animals and plants.
The present study illustrates how data from various large-scale differential screening analyses can be integrated into specific and/or global biological studies. Such comparisons of gene expression profiles are of value in understanding general expression profiles of all dividing cells and in analyzing differences between unicellular and multicellular organisms. They can also identify new signaling molecules and explain how different signals and transduction pathways could regulate the proliferation of different cell types. They can help elucidate the function of proteins, and finally they can identify abnormal patterns of gene expression in transformed and tumor cells. With the increasing amount of information being generated from microarrays and DNA chips, the potential value of comparative analyses will be all the greater.
Materials and methods
Cell culture
Suspension cultures of lactogen-dependent Nb2-11C lymphoma cells were grown in RPMI 1640 medium containing 10% fetal calf serum (FCS), 10% lactogen-free horse serum, 0.1 mM ß-mercaptoethanol, 2 mM L-glutamine, 5 mM HEPES pH 7.3, and penicillin-streptomycin (50 lU/ml and 50 µg/ml, respectively) at 37°C with 5% CO2. Cultures were rendered quiescent by transferring cells into starvation medium (cell density about 1.5 × 105 cells/ml), deficient in FCS and ß-mercaptoethanol, for 24 hours. Under these conditions, about 80-85% of the cells were arrested in the G0/G1 phase (Figure
RNA extraction, poly(A)+ RNA preparation, cDNA synthesis, northern blot and reverse northern blot analyses
For each cell population to be compared, RNA was prepared by acid guanidinium-thiocyanate-phenol-chloroform extraction [74] and poly(A)+ RNA was isolated using magnetic oligodT (Dynabeads, Dynal). Double-stranded cDNA was transcribed using a commercial kit (Boehringer). Northern blots were performed using the formaldehyde/formamide procedure and reverse northern blots as described in [75]. The Vacugene transfer system (Pharmacia), nylon filters (Hybond N+, Amersham) and the hybridization solution (ExpressHyb, Clontech) were used following the manufacturer's instructions. The cDNAs were radiolabeled using the Readyprime kit (Amersham).
mRNA differential display, representational difference analysis (RDA), subtractive suppressive hybridization (SSH) and organized library screening
Total RNA treated with DNase I was prepared from Nb2 cells treated for 0, 2, 4, 6, 8, 12 or 24 h with prolactin, and used in mRNA differential display using the GenHunter kit (GeneHunter Corporation, TN, USA). Poly(A)+ mRNA extracted from Nb2 cells treated with prolactin for 12 h was used for RDA according to the protocol described in [13]. SSH [14] was performed using poly(A)+ RNA obtained by mixing mRNA from Nb2 cells stimulated with ovine prolactin for 2, 4, 6 and 8 h. An organized rat brain library was screened as described in [15].
Preparation of complex probes, multiplex PCR and differential screening of candidate genes
In this technique, nylon filters dotted with candidate genes are hybridized with complex cDNA probes from different cell populations, to compare expression levels (see, for example [76]). Originally developed and validated by SANOFI-Recherche (unpublished data), the nylon filters contain 91 rat candidate genes (PCR products), including signaling molecules and transcription factors (Figure
The efficiency of the technique was controlled by including rabbit a and ß globin cDNAs on the nylon membranes along with the candidate genes. Defined amounts (50 or 150 ng) of the globin cDNAs were also added to the cDNAs mixtures before the multiplex PCR step. As expected, when these different amounts of rabbit globin cDNAs were added to the complex cDNAs, spots of different intensities were obtained (Figure
Figure
Sequencing
The potential positive clones isolated by differential display, RDA, SSH or screening of the organized library were sequenced with a dye terminator kit using the ABI Prism system (Perkin-Elmer).
Bioinformatics
To identify the sequenced cDNAs, BLAST and UniGene from NCBI were used [77]. For comparison, we have also consulted databases of transcripts differentially expressed during cell-cycle progression in human fibroblasts [27,28] and in