Higher Protein Kinase C ζ in Fatty Rat Liver and Its Effect on Insulin Actions in Primary Hepatocytes

We previously showed the impairment of insulin-regulated gene expression in the primary hepatocytes from Zucker fatty (ZF) rats, and its association with alterations of hepatic glucose and lipid metabolism. However, the molecular mechanism is unknown. A preliminary experiment shows that the expression level of protein kinase C ζ (PKCζ), a member of atypical PKC family, is higher in the liver and hepatocytes of ZF rats than that of Zucker lean (ZL) rats. Herein, we intend to investigate the roles of atypical protein kinase C in the regulation of hepatic gene expression. The insulin-regulated hepatic gene expression was evaluated in ZL primary hepatocytes treated with atypical PKC recombinant adenoviruses. Recombinant adenovirus-mediated overexpression of PKCζ, or the other atypical PKC member PKCι/λ, alters the basal and impairs the insulin-regulated expressions of glucokinase, sterol regulatory element-binding protein 1c, the cytosolic form of phosphoenolpyruvate carboxykinase, the catalytic subunit of glucose 6-phosphatase, and insulin like growth factor-binding protein 1 in ZL primary hepatocytes. PKCζ or PKCι/λ overexpression also reduces the protein level of insulin receptor substrate 1, and the insulin-induced phosphorylation of AKT at Ser473 and Thr308. Additionally, PKCι/λ overexpression impairs the insulin-induced Prckz expression, indicating the crosstalk between PKCζ and PKCι/λ. We conclude that the PKCζ expression is elevated in hepatocytes of insulin resistant ZF rats. Overexpressions of aPKCs in primary hepatocytes impair insulin signal transduction, and in turn, the down-stream insulin-regulated gene expression. These data suggest that elevation of aPKC expression may contribute to the hepatic insulin resistance at gene expression level.


Introduction
The normal physiological responses to insulin stimulation in the liver include the increase of glycolysis and lipogenesis, and the reduction of gluconeogenesis [1,2]. In hepatic parenchymal cells, insulin initiates a signaling cascade upon binding to its receptor on the cell membrane, which is followed by the activation of insulin receptor substrates (IRSs) [3]. Tyrosine overexpression of PKCz or PKCι/λ in ZL primary hepatocytes impaired the insulin-regulated gene expression.

Animals and diets
Zucker rats were bred and housed under constant temperature and humidity in the animal facility on a 12-hour light-dark cycle. Male ZL (fa/+ or +/+) or ZF (fa/fa) rats at weaning (3 weeks old) were kept on Teklad rodent chow ad libitum (#8640, Harlan Laboratories, Indianapolis, IN) for 8 weeks before liver tissue collection and primary hepatocyte isolation. All procedures were approved by the Institutional Animal Care and Use Committee at the University of Tennessee at Knoxville (Protocols #1256, 1642 and 1863).
Liver tissue collection, total protein preparation and total RNA extraction The rat was euthanized by primary carbon dioxide asphyxiation, and then secondary cervical dislocation according to regulations. The procedure for liver tissue collection was reported elsewhere [21,22]. In brief, a 10ml syringe with a 21G × 1½" hypodermic needle was used to drain blood from the liver via the inferior vena cava. The liver was excised, sliced, then snap-frozen in liquid nitrogen, and store at -80°C before further analysis. A small portion of the liver tissue was homogenized in 10 volumes of cold whole-cell lysis buffer (1% Triton X-100, 10% glycerol, 1% IGEPAL CA-630, 50mM Hepes, protease inhibitors, pH 8.0), and then centrifuged to remove insoluble matters [21,22]. The protein concentration of the supernatant was determined with PIERCE BCA protein assay kit. Another small portion of the liver tissue was homogenized in 10 volumes of cold STAT-60. Total RNA was extracted according to the manufacturer instructions.
Cloning of the rat Prkci cDNA and subcloning of the rat Prkcz cDNA Based upon the rat Prkci mRNA sequence (GenBank: EU517502.1), sense 5'-ATC CCC TCA GCC TCC AGC GG-3' and antisense 5'-ACT GTG ACC GGG CTA ACG GT-3' primers were designed using Primer-BLAST tools from the National Center Biotechnology Information. For the complete coding sequence of rat Prkci cDNA, PCR was carried out using cDNA derived from total RNA of ZL primary hepatocyte as the template. For subcloning of rat Prkcz, pEYFP-N1 vector containing its complete coding sequence (generous gift from Dr. Ralf Kubitz) was used as the template for the PCR amplification of Prkcz with sense primer 5'-ACC TCG AGA TGC CCA GCA GGA CCG AC-3' and antisense primer 5'-GTG AAT TCA CAC GGA CTC CTC AGC AGA C-3'. The amplicons containing the complete coding sequences of Prkci and Prkcz cDNA sequences were ligated into pCR2.1 vector through TA Cloning Kit (Invitrogen) according to the manufacturer's protocol.

Generation of Ad-Prkcz and Ad-Prkci recombinant adenoviruses
The inserts containing the complete coding sequences of Prkcz and Prkci were subcloned into pACCMV5 vector to make pACCMV5-Prkcz and pACCMV5-Prkci, respectively. To generate Ad-Prkcz and Ad-Prkci recombinant adenoviruses, pACCMV5 plasmid containing the complete coding sequence of atypical Prkc sequences was co-transfected with JM17 into HEK293 cells using FuGENE 1 6 Transfection Reagent (Roche) according to manufacturer instructions. After the formation of the viral plaques, the crude lysate was collected and stored at -80°C. The amplification and purification of adenovirus were carried out according to published protocols [23]. The optical density (OD) at 260nm of the adenoviral suspension was determined to estimate the plaque forming units (pfu) of the purified recombinant adenoviruses. We used that 1 OD equals to 1 × 10 12 pfu/ml. The purified recombinant adenoviruses were stored at -80°C until being used.

Infection of recombinant adenoviruses and treatments of primary hepatocytes
In experiments using recombinant adenoviruses, purified Ad-Prkcz and Ad-Prkci were added in the medium A (5,000 pfu/cell) to allow the overexpression of PKCz and PKCι/λ in the primary rat hepatocytes during the pretreatment period, respectively. The pretreated hepatocytes were then washed once with PBS, and treated with medium A containing indicated concentrations of insulin (0nM to 100nM) for 6 hours before total RNA extraction, or for 15 minutes before whole cell lysate preparation.

Immunoblot analysis of proteins
Protein samples (40μg) of the whole cell lysates of primary hepatocytes or liver tissues were resolved in 8% SDS polyacrylamide gel, and then transferred to BIO-RAD Immuno-Blot PVDF membrane (Hercules, CA) as described [23]. Membranes were blocked by 8% non-fat milk, and then probed with specific antibodies (1:1 000 dilution). After gentle wash, membranes were incubated with goat anti-rabbit IgG conjugated with horseradish peroxidase (1:5,000 dilution). After washing, antigen-bound antibody was detected using ECL Western Blotting Substrate (Thermo Scientific), and subsequently exposure to X-ray films. The films were scanned, and the images were stored for the densitometry analysis using ImageJ software (NIH). Densitometry data for each protein were normalized to β-actin levels in each sample.

Statistical Analysis
Statistical analyses were performed using SPSS 19.0 software. Student t-test was used to compare the means between two groups. One-way ANOVA with LSD post-hoc test was used to compare the means among three or more groups. Data were presented as means ± S.E.M. The number of experiments indicates hepatocyte isolations from different animals. A p value less than 0.05 is considered statistically significant.

Results
PKCζ expression is elevated in the liver of ZF rats Fig. 1A shows that, despite the well-reported hepatic insulin resistance, the levels of phospho-AKT at Ser473 and Thr450 in the liver of ZF rats were higher than that of ZL rats (please see densitometry analysis in S1 Fig.). The phospho-AKT at Thr308 in the liver tissues could not be detected in the current experimental condition, probably due to non-maximal activation of AKT in ad libitum state, relative less AKT protein amount from hepatocytes in the liver tissue lysate or rapid de-phosphorylation of AKT at Thr308 during the process of euthanasia of the animals. This observation shows that the AKT phosphorylation at Ser473 and Thr450 in ZF rat liver tissue is unimpaired, suggesting the consequence of hyperinsulinemia. In addition, ZF rat liver had higher protein level of FAS, indicating elevation of hepatic lipogenesis.
On the other hand, the protein level of PKCz, but not PKCι/λ, in the liver of ZF rats was higher than that of ZL rats (Fig. 1A). The level of phospho-PKCz/λ at Thr410/403, which indicated the phosphorylation of both PKCz and PKC ι/λ, was higher in the liver samples of ZF rats than that of ZL rats (Fig. 1A). The mRNA level of Prkcz, but not that of Prkci, was also elevated in the ZF liver (Fig. 1B). These data collectively demonstrated that the aPKC expression levels changes with the development of hepatic insulin resistance in the ZF liver.
Short-term insulin treatment did not alter protein levels of total and phospho-aPKCs in primary rat hepatocytes Fig. 2 shows that protein levels of FAS, ACC and phospho-ACC at Ser79 in hepatocytes of ZF rats were higher than that of ZL rats. This result demonstrates that the hepatic lipogenic capability remains elevated in ZF hepatocytes cultured for 20 hours. Insulin treatment dose-dependently induced the levels of phospho-AKT at Ser473 and Thr308 in ZL and ZF primary hepatocytes similarly (Fig. 2). The level of phospho-AKT at Thr450, which was insulin-independent, was slightly higher in ZF hepatocytes than in ZL hepatocytes (Fig. 2). These data demonstrated that the insulin-induced AKT phosphorylation is comparable in both ZL and ZF rat hepatocytes. The impaired insulin-regulated gene expression in ZF hepatocytes may be caused by changes in other components of insulin signaling pathway. On the other hand, the aPKC Overexpression and Hepatic Gene Expression 15-minute insulin treatment did not significantly induce or suppress the protein levels of PKCz and PKCι/λ and phospho-PKCz/λ at Thr410/403 in ZL and ZF primary hepatocytes (Fig. 2). There was a slight induction of the total PKCz when fresh M199 was added. ZF primary hepatocytes had higher level of PKCz than ZL primary hepatocytes (Fig. 2), which was in line with the finding from the liver tissues ( Fig. 1).

Overexpressions of PKCζ and PKCι/λ in ZL primary hepatocytes
To investigate whether elevated aPKC protein levels contribute to the hepatic insulin resistance at gene expression level, we constructed recombinant adenoviruses Ad-Prkcz and Ad-Prkci for their overexpressions in ZL primary rat hepatocytes. The expression level of Pckcz or Prkci mRNA was normalized to that of ribosomal gene 36B4, which was stable across all treatment groups (S2 Fig.). In hepatocytes transfected with Ad-β-gal, the relative abundance of Prkcz mRNA (-ΔCt of -7.90) was much lower than that of Prkci mRNA (-ΔCt of -4.20). The overexpression fold of Pckcz or Prkci was calculated using their levels in the Ad-β-gal group as 1. Ad-Prkcz and Ad-Prkci respectively caused overexpressions of Prkcz mRNA (-ΔCt of 3.13,~2 000 fold, Fig. 3A) and Prkci mRNA (-ΔCt of 3.78,~250 fold, Fig. 3B, Ã ).
Interestingly, 0.1-100nM insulin treatments significantly suppressed the expression levels of Prkcz mRNA by 40-60% in hepatocytes transfected with Ad-Prkci (Fig. 3A, black columns). Acute insulin treatment did not alter protein levels of total and phospho-aPKCs in primary hepatocytes from ZL and ZF rats. The primary hepatocytes from ZL and ZF rats (chow diet, 8 weeks) were pre-treated as described in the Materials and Methods for overnight, and then incubated in fresh medium A with increasing concentrations of insulin (0nM to 100nM) for 15 min. The hepatocyte group remained in pre-treatment medium was indicated by "C". Immunoblot analysis with antibodies against the indicated proteins was performed. The figure shows the representative result of three parallel experiments obtained from three sets of primary hepatocytes independently isolated from ZL and ZF rats fed chow diet ad libitum. On the other hand, in hepatocytes transfected with Ad-Prkcz, the expression levels of Prkci mRNA in 1-100nM insulin treatment groups were significantly lower than that in hepatocytes with β-GAL overexpression at the corresponding treatments (Fig. 3B, striped columns, #). Fig. 4 shows that PKCz, but not PKCι/λ, protein level was overexpressed by~9.3 folds in hepatocytes transfected with Ad-Prkcz compared to that with Ad-β-gal. Overexpression of PKCz did not significantly increase phospho-PKCz/λ Thr410/403 level. Fig. 5 shows that primary rat hepatocytes transfected with Ad-Prkci manifested~4.0 fold overexpression of PKCι/λ protein and increased phosphorylation of PKCz/λ at Thr410/403, compared to that with Ad-β-gal. Unfortunately, we tried and failed to develop a method for the determination of activities of PKCz and PKCƖ/λ using substrates as reported and available antibodies.
Overexpression of PKCζ or PKCι/λ attenuated the insulin signaling cascade in ZL primary hepatocytes Fig. 4 shows that the levels of insulin-induced phosphorylation of AKT at Ser473 and Thr308, and insulin-independent phosphorylation of AKT at Thr450, were diminished in hepatocytes overexpressing PKCz, but not β-GAL. There was no change of total AKT. The expression levels of IRS1 were also lowered upon the overexpression of PKCz. Interestingly, based on the densitometry analysis, there was a slight but significant elevation in the levels of PKCι/λ, FAS, ACC or phospho-ACC at Ser79 in the hepatocytes overexpressing PKCz compared with Ad-β-gal group (S3 Fig.). Fig. 5 shows that PKCι/λ overexpression did not significantly change the expression levels of PKCz and ACC in ZL primary hepatocytes. The levels of FAS and phospho-ACC Ser79 were marginally but significantly elevated (S4 Fig.). PKCι/λ overexpression did not change the total AKT level compared with Ad-β-gal group. Similar to that in PKCz overexpression groups, the levels of IRS1, insulin-induced phospho-AKT at Ser473 and Thr308, and insulin-independent phosphorylation of AKT at Thr450 were significantly decreased in primary rat hepatocytes overexpressing PKCι/λ in comparison to the Ad-β-gal group. These data collectively demonstrate that overexpression of aPKC attenuates the activation of insulin signaling cascade in primary hepatocytes from ZL rats.

Overexpression of PKCζ or PKCι/ζ impaired the expression levels of insulin-regulated genes in primary hepatocytes from ZL rats
Insulin dose-dependently induced the expression levels of Gck (Fig. 6A) and Srebp-1c (Fig. 6B) transcripts in Ad-β-gal group. Overexpression of PKCz or PKCι/λ increased the basal levels of Gck and Srebp-1c in ZL primary hepatocytes. However, overexpression of PKCz or PKCι/λ abolished the insulin-induced Gck and Srebp-1c expressions in ZL hepatocytes.

Discussion
Here we show that the expression levels of PKCz protein and Prkcz mRNA are higher in the liver of ZF rats than ZL rats. This elevation remains intact in primary hepatocytes that have been cultured for more than 20 h. Since the insulin-regulated gene expression is impaired in primary hepatocytes from ZF rats, we hypothesize that the alteration of aPKC expressions may play a role in this impairment. Therefore, PKCz and PKCι/λ are successfully overexpressed using recombinant adenoviruses in ZL primary hepatocytes. The adenoviral-mediated overexpression of PKCz or PKCι/λ in primary hepatocytes from ZL rats leads to the impairment of insulin-regulated Gck, Srebp-1c, Pck1, G6pc and Igfbp1 expressions (Fig. 6). Overexpression of  either PKCz or PKCι/λ is sufficient to alter basal and insulin-regulated gene expression in hepatocytes from ZL rats.
The impairment of the insulin-regulated gene expression might be attributed to the reduction of of AKT phosphorylations in cells with overexpression of PKCz or PKCι/λ., Maximal activation of AKT needs phosphorylations of AKT at both Ser473 and Thr308 as indicated in [4]. Therefore, detection of its phosphorylation using specific antibodies have been a indicator of AKT activation status. It was interesting to note that we could not detect phosphorylation of AKT at Thr308 in the liver tissue lysates of both ZL and ZF rats. Here are the possible reasons. First, the in vivo activation of AKT may be moderate, not maximized, which allows further regulation in response to stimuli. Second, there might be relative less AKT protein amount from hepatocytes in the liver tissue preparations, which requires a larger amount of protein per sample for the detection. Third, the phosphorylation of AKT at Thr308 in the liver may be rapidly de-phoshorylated during the time when the animals were euthanized for the collection of tissue samples. Nevertheless, we demonstrated here that in ZL hepatocytes of Ad-β-gal group, insulin dose-dependently induces the levels of phospho-AKT (Ser473 and Thr308) and IRS1 protein.
On the other hand, PKCz or PKCι/λ overexpression attenuates the insulin-induced phosphorylation of AKT, and decreases the protein level of IRS1, which suggests a diminished signaling cascade initiated from IRS1 upon insulin treatment (Figs. 4 and 5). Without insulin treatment, the expression level of total AKT and p-AKT seem to be not different between the Ad-β-gal control and aPKCs overexpression groups (Figs. 4 and 5). However, higher mRNA levels of Gck, Pck1, Srebp-1c and Pklr were observed in the aPKCs overexpression groups compared to those in the Ad-β-gal control (Fig. 6). This indicates that other mechanisms may contribute to the elevation of the basal expression of those genes in hepatocytes overexpressing PKCz or PKCι/λ. GCK catalyzes the phosphorylation of glucose into glucose-6-phosphate, which is the ratelimiting step of glycolysis in the liver [24]. The induction of the hepatic Gck expression depends on the activation of insulin signaling pathway in the liver [11]. PKCz (Fig. 4) or PKCι/λ (Fig. 5) overexpression diminished phosphorylation of AKT at Ser473 along with the decrease of IRS1 protein expression. It has been reported that aPKCs probably act as negative feedback regulators of insulin signaling pathway by promoting serine phosphorylation and tyrosine dephosphorylation of IRS proteins both in vitro and in cell lines [25][26][27]. Thus, the reduction of the activation of insulin signaling pathway due to PKCz or PKCι/λ overexpression may impair the insulin-regulated Gck expression. Additionally, the insulin-induced Gck expression has been suggested to be mediated by transcription factors, such as hepatocyte nuclear factor 4, forkhead box protein O1, SREBP-1c, liver x receptor α, and peroxisome proliferator-activated receptor γ [28][29][30][31]. Since the knowledge about the non-kinase activities and endogenous substrates of PKCz or PKCι/λ is limited, it is possible that PKCz or PKCι/λ directly regulate Gck expression through controlling the activation of certain transcription factors at its promoter, which increases the Gck basal mRNA level.
PEPCK catalyzes the rate limiting enzymatic reaction in gluconeogenesis, by which oxaloacetate is converted into phosphoenolpyruvate [32]. In the liver, the insulin-suppressed Pck1 expression has been thought to be purportedly mediated through three pathways: (1) the phosphorylation and inactivation of forkhead box proteins by insulin [33,34]; (2) antagonizing arbitrarily set to 1 for that gene. The mRNA levels of (A) Gck, (B) Srebp-1c, (C) Pck1, (D) Igfbp-1, (E) G6pc and (F) Pklr were expressed as fold inductions (mean ± SEM; n = 4; all p<0.05; a<b, c<d, e>f, g>h, i>j, k>l, m>n, o>p, q>r for comparing the insulin treatment groups of hepatocytes overexpressing Adβ-gal, Ad-Prkcz or Ad-Prkci using one-way ANOVA; * for comparing fold inductions among Ad-β-gal, Ad-Prkcz and Ad-Prkci groups at the indicated insulin concentrations using one-way ANOVA). doi:10.1371/journal.pone.0121890.g006 aPKC Overexpression and Hepatic Gene Expression the glucagon-induced PPARγ co-activator 1 expression [35]; (3) the phosphorylation of CREBbinding protein via aPKCs [36,37]. Interestingly, insulin-induced activation of aPKCs was shown to suppress Pck1 expression via this phosphorylation of SREBP-binding protein [36]. However, our results show the induction of Pck1 expression upon overexpression of PKCz or PKCƖ/λ in the absence of insulin. The activities of aPKC isoforms are elevated in the liver of individuals with type 2 diabetes [17]. Treatment of hepatocytes from these individuals with aPKC inhibitors decreases the basal transcript levels of gluconeogenic genes [17]. Hepatic inhibitors of PKCƖ have been show to correct the metabolic abnormalities in rodents [18]. Here, aPKCs overexpression not only increases the basal transcript of Pck1 mRNA, but also abrogates the insulin-suppressed Pck1 expression. Additionally, aPKCs overexpression attenuates the insulin-suppressed G6pc expression. Therefore, our data suggest that aPKCs are prominent positive regulators of hepatic gluconeogenesis.
SREBP-1c is a master regulator of the hepatic expression of lipogenic genes [38]. The insulin-induced Srebp-1c expression requires the activation of PI3K, and the mTORC2-mediated phosphorylation of AKT at Ser473 [39]. Based on the use of pharmacological inhibitors, the activation of mTORC1 downstream of AKT is identified as an indispensible step in the induction of Srebp-1c [39]. On the other hand, the activation of PI3K subsequently activates aPKC in the liver, which promotes Srebp-1c expression and lipogenesis [12,13]. Despite the diminished activation of AKT and the abolished insulin-induced Srebp-1c expression, PKCz or PKCι/λ overexpression increases the basal transcript level of Srebp-1c in the primary hepatocytes from ZL rats (Fig. 6C). Interestingly, PKCz or PKCι/λ overexpression only marginally induced the protein levels of FAS and ACC (Figs. 4 and 5). One possibility is that the elevation levels of transcripts might not have been translated in the presence of overexpression of PKCz or PKCι/λ. Alternatively, diminished insulin signaling pathway results in decreased activation of p70 S6-kinase, which is required for the SREBP-1c processing to generate nuclear SREBP-1c [40]. Moreover, there might be a lag time between the elevation of Srebp-1c mRNA and the increase of SREBP-1c protein, and the down-stream targets. Nevertheless, the protein levels of ACC and are maintained at a high level in the hepatocytes and liver samples of ZF rats (Figs. 1 and 2), demonstrating the metabolic changes associated with these insulin-resistant animals. Further investigations are needed to delineate the sequential events associated with the elevation of the hepatic lipogenesis upon insulin stimulation and activation of AKT and aPKC isoforms.
It is interesting to note that the Prkcz mRNA and PKCz protein, but not that of Prkci mRNA and PKCι/λ protein levels are elevated in the liver of ZF rats. Insulin at 1nM and up significantly induces the expression levels of Prkci mRNA, a process that is blunted in the presence of PKCz overexpression. On the other hand, insulin does not affect the expression of Prkcz mRNA. Additionally, PKCι/λ overexpression alone does not affect Prkcz mRNA expression. However, PKCι/λ overexpression introduced the insulin-mediated suppression of Prkcz mRNA expression. These data indicate that there are crosstalks between PKCz and PKCι/λ pathways, which may mutually regulate the expression of each other at mRNA levels in response to hormonal or nutritional stimuli. The alteration of this mutual regulation mechanism probably is associated with the development of the impairment of insulin signaling cascade. Further studies are warranted.
It is worth noting that, in ZL primary hepatocytes, the overexpression of aPKCs and the attenuated insulin signaling cascade lead to abolishment of insulin-regulated expression of Gck, Pck1 and Srebp-1c (Fig. 6). In contrast, ZF rats showed unimpaired phosphorylation of AKT at Ser473 and Thr450 despite increased PKCz levels (Figs. 1 and 2). This difference may explain that the insulin-regulated expression of Gck and Pck1 is impaired rather than abolished in ZF primary hepatocytes [41]. Additionally, in high-fat diet fed mice, increased basal AKT phosphorylation was observed in the liver with indication for the development of insulin resistance [42]. Additionally, elevated aPKC activity was shown to attenuate AKT-dependent FOXO1 phosphorylation in the liver of diet-induced obesity mice, despite concurrent elevated hepatic AKT activity [43]. These data collectively suggest that activation statuses of both AKT and aPKC are critical in the regulation of hepatic insulin sensitivity.
In summary, we have shown that the expression level of PKCz is elevated in insulinresistant animals. Overexpression of PKCz or PKCƖ/λ in ZL primary hepatocytes reduces the activation of AKT probably through the reduction of IRS1 expression, demonstrating the attenuation of the activation of insulin signal pathway. This alteration of the expression levels of aPKC leads to the impairment of the insulin-regulated gene expression in primary hepatocytes. Our data demonstrate the critical roles of aPKCs in the regulation of hepatic insulin-sensitivity at gene expression level, and provide insights into the development of the insulin resistance and type 2 diabetes.
Supporting Information S1 Fig. Densitometry analysis of target proteins in the livers of ZL and ZF rats. Densitometry analysis was performed using ImageJ software (NIH). The data for each protein were normalized to β-actin levels in each sample. One-way ANOVA with LSD post-hoc test was used to compare the means. Error bars represent S.E.M. Ã indicates a p value less than 0.05. (DOCX) S2 Fig. Ct number of the ribosomal gene 36B4 in ZL hepatocytes transfected with Ad-β-gal, Ad-Prkcz and Ad-Prkci, respectively. Primary hepatocytes of ZL rats fed chow for 8 weeks were isolated and seeded onto dishes as described in the Materials and Methods. Purified Adβ-gal, Ad-Prkcz and Ad-Prkci were added in medium A during the overnight pretreatment period to allow the overexpression of β-GAL, PKCz and PKCι/λ, respectively. The primary hepatocytes were then incubated in fresh medium A with increasing concentrations of insulin (0 nM to 100 nM) for 6 hours before total RNA extraction. Total RNA was extracted, and then subjected to real-time PCR analysis with primer pairs for 36B4. The data were the raw Ct number of 36B4 for 0 nM insulin treatment groups (mean ± SEM; n = 4). (DOCX) S3 Fig. Densitometry analysis of target proteins in ZL hepatocytes transfected with Ad-βgal or Ad-Prkcz. Densitometry analysis was performed using ImageJ software (NIH). The data for each protein were normalized to β-actin levels in each sample. Two-way ANOVA was used to determine the contribution of insulin treatment and adenovirus overexpression to total variance. Error bars represent S.E.M. Ã indicates that adenovirus overexpression accounts for a significant percentage of total variance with a p value less than 0.05. a<b, c<d<e, which indicate insulin treatments account for a significant percentage of total variance with a p value less than 0.05. (DOCX) S4 Fig. Densitometry analysis of target proteins in ZL hepatocytes transfected with Ad-βgal or Ad-Prkci. Densitometry analysis was performed using ImageJ software (NIH). The data for each protein were normalized to β-actin levels in each sample. Two-way ANOVA was used to determine the contribution of insulin treatment and adenovirus overexpression to total variance. Error bars represent S.E.M. Ã indicates that adenovirus overexpression accounts for a significant percentage of total variance with a p value less than 0.05. a<b, a'<b', c<d, e<f, which indicate insulin treatments account for a significant percentage of total variance with a p value less than 0.05. (DOCX)