1.

Introduction

Thermal injury is associated with a pronounced catabolic response in tissue reflecting both reduced protein synthesis and stimulated protein breakdown.¹ The effect of acute heat shock in cells ranges from survival and adaptation through alterations in gene expression to cellular death by apoptosis and necrosis after severe thermal stress.² The effects of thermal stress on tissue can be due to a direct effect on cellular constituents (denaturation of proteins) or as a secondary effect mediated by adaptive mechanisms like the expression of heat shock proteins (hsp) and inflammation. The effects of moderate heat on cellular structure and function have been well established, and hsp expression has been linked to numerous physiological changes in the cell that can affect cell cycle, cellular differentiation, and apoptosis.^{3, 4, 5, 6}

Thermal effects have been largely studied in cultured cells, and there is a need for a better understanding of tissue responses to hyperthermia. In tissues, the cellular stress response does not occur in isolation but rather occurs in the context of the tissue matrix, multiple cell types, and integrated physiology leading to an inflammatory response. The epidermis is a physiological barrier that protects the organism against constant irradiation of the skin, which would result in DNA damage, apoptosis, and transcriptional changes. Cutaneous defensive mechanisms are highly complex and involve DNA repair, release of pro-inflammatory intercellular signaling molecules, and activation of specific signal transduction cascades that result in activation of transcription factors and regulation of gene expression. ^{7, 8, 9, 10, 11, 12, 13} The increased usage of lasers in medicine, research, and military applications has caused an increase in laser injury, particularly to the eye.¹⁴ Laser damage to tissue can be categorized into three basic types: photomechanical, photochemical, and photothermal. Of these basic categories, photothermal damage seems to be the most important.

Gene expression profiling of cultured cells has shown that the pathophysiology following laser damage closely parallels the response following burn injuries.^{14, 15, 16} In comparison to scalpel incisions, those made by lasers in surgery generally have the disadvantage of causing a delay in wound healing due to collateral thermal damage to surrounding tissues. This was demonstrated in a study where differences in gene expression between free electron laser (FEL) and scalpel incisions in mouse skin were analyzed. It was shown that there was significant differential expression between scalpel and FEL wounds of 89 genes using a 15000-gene microarray.¹⁷

DNA microarray analysis has proven to be an informative tool for multiplexed gene expression studies and was applied here to assess acute tissue responses to laser-induced thermal stress. Enk ¹⁸ have investigated differential expression of ultraviolet-regulated genes in intact human epidermis following in vivo exposure with microarray profiling of 12500 genes. This allowed for differentiation between irradiated and nonirradiated epidermis allowing for the identification of 800 ultraviolet-regulated genes.

It has been widely shown that changes in gene expression are integral for the cellular response to thermal stress. Although genes encoding hsps have been well studied, thermal stress leads to increased expression of a substantial number of genes not normally considered to be hsps.^{19, 20} These genes can be affected by a variety of different stressors and therefore represent a nonspecific cellular response to stress. Analysis of the inactivation of keratinocytes from short exposure (on the order of seconds) to high temperatures (50 to 60°C) indicated that the absorbing species and/or the injury and response mechanisms may be different from injuries caused by prolonged exposure to moderately elevated temperatures (40 to 50°C for 10 to 20 min).²¹

To study the tissue response to thermal stress, we developed a transgenic reporter mouse where the transgene is comprised of the promoter from hsp70A1 and the coding sequence for luciferase fused to green fluorescent protein (GFP).²² Tissues in this reporter mouse, called hsp70-L2G, respond with bioluminescence and fluorescence to exposure to elevated temperatures. Using this mouse we were able to precisely identify the times and temperatures that induced an hsp response after irradiation with a CO₂ laser. Hsp70-L2G expression demarcated the region of extreme thermal injury, the response of surrounding tissue, and the unaffected regions. We used this expression as a guide to study thermal stress in the mouse epidermis. Gene expression patterns in the two stress regions were compared with that of normal epidermis using DNA microarrays. We identified twenty-three genes with a ten-fold change of expression in the laser-treated region and thirteen genes with a ten-fold change in the adjacent region. Expression of the chemokine Cxcl3 was increased to the greatest extent among all of the genes examined. Altered expression levels for eleven specific genes, including Cxcl3, were validated using quantitative reverse transcription-polymerase chain reaction (qRT-PCR).

2.

Materials and Methods

2.1.

Transgenic Reporter Mouse

The transgenic mouse used for bioluminescent analysis of laser stress was first described by O’Connell-Rodwell ²² Briefly, the transgenic mouse employed the dual reporter gene L2G (Luc-2A-eGFP) consisting of a modified firefly luciferase gene (pGL3, Promega Inc., Madison, Wisconsin) joined to 54 base pairs (bp) of the foot-and-mouth disease virus 2A sequence and, via 24 bp of polylinker sequence, to the eGFP gene at the 3^′ end. The reporter genes are driven by the murine HSP70A1 promoter sequence. The reporter gene construct is shown in Fig. 1a. Potential founder mice were screened by PCR and tested for thermal response by exposure to mild thermal stress and bioluminescence imaging using an in vivo imaging system (IVIS) imaging system (a Xenogen product form Caliper Life Sciences, Alameda, California) (see below). The selected transgenic mouse line [friend virus B (FVB).Hsp70-luc_2A-eGFP; short form: Hsp70-L2G] was bred to homozygosity, and four to eight week old female mice were used for the in vivo experiments. All research performed in this study was approved by the Stanford University Administrative Panel for Laboratory Animal Care and were conducted under strict adherence to institutional guidelines for animal care.

Fig. 1

(a) Hsp70 reporter construct. (b) Bioluminescent imaging of the 6-mm laser spot at the 7-h time point. (c) This figure is color coded to reveal genes largely involved in angiogenesis, apoptosis, inflammation, and cellular stress. The numbers in the inner circle indicate the number of up-regulated genes (>4-fold change) related to each functional region in the 6-mm laser treated spot. The numbers in the “donut” region surrounding the inner circle are the number of up-regulated genes (>4-fold change) related to each colored functional region in the location adjacent to the laser treated spot.

2.5.

Relative Expression Quantification by Real Time qRT-PCR

Expression of putatively differentially expressed genes was quantified by SYBR Green real time qRT-PCR on laser treated and control tissue. RNA was isolated using the RNeasy fibrous tissue kit (Qiagen, Valencia, California). DNase treated total RNA was reverse transcribed using Multiscribe Reverse Transcriptase and random hexamers (AppliedBiosystems, Alameda, California) according to the manufacturer's instructions. Quantitative qRT-PCR analyses were performed with an iCycler iQ(Bio-Rad, Hercules, California) using Quantitect PCR Master Mix (Qiagen). Individual expression values were normalized to 18S rRNA expression (Pre-Developed TaqMan Assay Reagents Control Kit; AppliedBiosystems). Primer design was done with help of the “Primer Express 2.0” software (AppliedBiosystems), according to the manufacturer's guidelines. To prevent amplification of genomic sequences at least one primer of each pair was designed spanning two exons where possible. The primer sequences that were used are shown in Table 1. Specificity of amplification was furthermore checked by melting curve analysis with help of the iCycler iQ software (Bio-Rad). Primer oligonucleotides were purchased from Operon (Huntsville, Alabama). PCR conditions were: initial denaturation for 10 min at 95°C followed by 45 cycles consisting of 15 s at 95°C and 1 min at 60°C. Expression ratios between two samples were calculated from differences in threshold cycles at which an exponential increase in reporter fluorescence could first be detected (C_T-values). Results of triplicates were averaged for tissue collected at 1-, 3-, and 7-h post-irradiation.

Fig. 3

qRT-PCR analysis was performed at 1-, 3-, and 7-h post-laser treatment of the laser spot and the adjacent tissue region compared to control for the eleven up-regulated genes of interest. In addition to the genes of interest, qRT-PCR on luciferase for the transgenic mouse was performed at seven hours as a control. Luciferase up-regulation is the highest at the 7-h time-point, so its analysis was only performed at that time for comparison. The results have been plotted in order from highest to lowest up-regulation of the genes of interest and are shown with relative expression at the three time points where available. qRT-PCR was performed for each time-point shown for each specific gene. In instances where data are not shown for a specific gene, there were no measureable expression changes for that gene (minimum of n = 3).

Table 1

Forward and reverse primer sequences used for SYBR Green qRT-PCR analysis of gene expression.

Entrez Gene	Entrez Gene
Gene ID	Symbol2	Gene Name	Forward	Reverse
330122	Cxcl3	chemokine (C-X-C motif) ligand 3	AGTCATAGCCACTCTCAAGGATGG	TGGACTTGCCGCTCTTCAGTA
16193	Il6	interleukin 6	CGCTATGAAGTTCCTCTCTGCAA	TGGTATCCTCTGTGAAGTCTCCTCTC
11910	Atf3	activating transcription factor 3	AGTCACCAAGTCTGAGGCGG	CTCCAGTTTCTCTGACTCTTTCTGC
18787	Serpine1	serine peptidase inhibitor, clade 3, member 1	TGGGATTCAAAGTCAATGAGAAGG	GCATCCGCAGTACTGATCTCATTC
15116	Has1	hyaluronan synthase 1	GTGGACTACGTGCAGGTCTGTG	CTCAAGAAGCTGACCCAGGAGT
16878	Lif	leukemia inhibitory factor 3	TAATGAAGGTCTTGGCCGCAG	TGATCTGGTTCATGAGGTTGCC
193740	Hspa1a	heat shock protein 1a (Hsp70)	ATCGAGGAGGTGGATTAGAGGC	ACCTTGACAGTAATCGGTGCCC
15525	Hspa4	heat shock protein 4	CTGTGTCATCTCAGTCCCATCCTT	GCAACAGCCGTCATGTCATTC
11838	Arc	activity regulated cytoskeletal-associated protein	GCTGAAGGTGAAGACAAGCCAG	CTGCTCAAGCTGCAGAGGCTAA
17384	Mmp10	matrix metallopeptidase 10	CCCACATCACCACAGGATTGTG	CCTTCAGAGATCCTGGAGAAAGTG
17082	Il1rl1	interleukin 1 receptor-like 1	CTTGTGTTATCAGAAGCCCCAACT	CCAAGCTGCAATATCCCTGATTA
–	pGL31	firefly luciferase	GGATTACCAGGGATTTCAGTCGAT	GGTAGATGAGATGTGACGAACGTGT

^aPromega luciferase reporter vector

^bEntrez Gene: gene-centered information at NCBI version v.33, official Gene ID, symbol, and name

3.

Results

The first step in identifying differentially regulated genes following laser thermal stress with a CO₂ laser was to image luciferase expression patterns in irradiated hsp70-L2G transgenic mice after stress induction. BLI identified the zones of differential hsp expression and guided tissue selection for microarray analysis. Previous studies that used a 1-s laser pulse duration had shown large differences in the stress response of tissue among the 23 different energies used. It was determined that 4.4 J/cm² of laser energy with a 1-s pulse duration resulted in two very different regions of interest for analysis. By using a 6-mm diameter laser spot, we were able to obtain a thermally damaged region of sufficient size to provide enough RNA for analysis. The images reveal that there is limited expression of hsp70-L2G at the laser spot, but expression levels in the surrounding region were high [Fig. 1b]. The signal intensity in the region surrounding the laser spot showed a significant increase in the bioluminescent signal and clearly demarcated the normal and laser treated regions; the region surrounding the laser spot can be seen as a ring of increased luciferase activity. These two regions and an untreated nearby control region were collected for comparison.

BLI revealed three zones of differential hsp expression and served as a guide for tissue selection. The laser treatment was repeated with wildtype mice and the tissues were collected for each of the zones and analyzed for gene expression patterns. Mice were treated with one 6-mm flat-top laser spot at the center of the shaved dorsum, and allowed to recover for seven hours. BLI indicated that luciferase expression from the hsp70 promoter peaked at seven hours. Data analysis showed distinctively different results between the two regions, the laser spot and the adjacent laser region, in comparison to untreated tissue.

Analysis of raw expression data from 14000 mouse genes identified a 4-fold induction of 596 genes for the laser versus untreated analysis compared with 69 genes for the adjacent laser region versus untreated. When comparing these regions for genes with a 10-fold change, 23 genes were found for the laser versus normal analysis compared to 13 genes for the adjacent laser region versus normal tissue.

The list of 4-fold, or greater, induced genes was then analyzed to classify genes according to their role in angiogenesis, apoptosis, inflammation, and stress for the two regions of interest compared to normal tissue. The number of genes for each of the four biological processes is shown in the pie chart in Fig. 1c where the central region represents the laser region and the surrounding donut represents the adjacent laser region. Figure 2 shows a cluster analysis (heat map) of both the 4- and 10-fold changes in genes for both regions of interest when compared to untreated tissue. The genes that displayed a 4-fold or greater increase are shown in yellow, orange, and red coloring at the top of the map. Down-regulated genes are indicated in blue. The adjacent region did not show any genes that were decreased in expression. The gene symbols were added for those genes that are increased 10-fold or greater for reference. In addition, labels were added, where appropriate, to show the genes that are characterized as those involved in apoptosis, inflammation, and stress.

Fig. 2

The highest expressed genes from the laser spot and the adjacent tissue are shown in a gene cluster at the 4- and 10-fold ranges. The green gene tree shows a hierarchical relationship and gene clustering. The gene symbols of the 10-fold up- or down-regulated genes are labeled at their location in the cluster. Each gene is labeled related to apoptosis, inflammation, and stress. No angiogenesis was seen at or above the 10-fold change.

Microarray analyses are useful for assessing global changes and identifying genes of interest, and expression patterns of selected genes can then be verified using qRT-PCR. We selected eleven genes for further analysis based on either their level of up-regulation or their function. The genes that were selected for their high levels of transcriptional induction were Cxcl3, Il6, Atf3, Serpine1, Has1, Lif, Hspa1a (Hsp70), Hspa4, Arc, Mmp10, and Il1rl1. Since we were interested in the early tissue response prior to inflammatory infiltrates appearing, we performed qRT-PCR at 1- and 3-h after laser treatment, in addition to the 7-h time point (peak Hsp70-luc expression). The results of the qRT-PCR analysis are shown in Fig. 3 starting with the highest levels of increased expression in the upper left and continuing down to the lower right of the figure. In addition to the eleven genes of interest, qRT-PCR was performed on luciferase for comparison with tissues from the transgenic hsp70-L2G mouse. A minimum of three mice were used for each analysis at each of the three time points. Missing bars indicate RNA levels below detection threshold.

4.

Discussion

The overall goal of this study was to identify genes that show differential gene expression immediately following laser stress/damage. We used the peak of hsp70-luc transcription (7-h) as a guide for early gene activation in vivo, and since induction of transcription takes at least one hour, we focused on the 1- to 7-h time period. Genes that are activated during this period have utility in assessing early tissue responses to stress, and their promoters could be used to drive reporter gene expression as indicators of tissue response to stress or to drive therapeutic gene expression in a directed fashion for use in genetic therapies. Directed therapies using thermal control of transcription could be used in a variety of applications where expression could be controlled by lasers or focused ultrasound. The promoters that most rapidly respond to thermal stress have the greatest utility and were therefore the focus of this study. Such genetic constructs could also be used to improve wound healing and survival following thermal injury. Alternatively, the products of the early response gene could be used as targets to develop small molecules that can modulate the healing response.

The thermal stress/damage of the laser spot was at a level that limited the immediate transcriptional activation of nearly all genes studied; however, by comparing the expression patterns in this region with that of surrounding regions we were able to identify genes that mark the acute response. The qRT-PCR at different time-points revealed increased expression of selected genes in the most thermally damaged laser region. The high levels of transcriptional activation for the chemokine Cxcl3 was confirmed by qRT-PCR. The microarray data showed a 24-fold increase in the laser spot and a 32-fold increase in the adjacent laser region. qRT-PCR indicated a more than 600-fold increase for the laser spot and a more than 100-fold increase for the adjacent laser region. These extremely high levels of transcriptional induction indicated that the promoter from Cxcl3 may have tremendous utility as a reporter for driving the expression of therapeutic genes. In reporter constructs, the significant dynamic range of this pattern would enable easy visualization of thermal stress. In therapeutic constructs, this promoter could be used to drive immediate and extreme levels of expression of a targeted gene. This would constitute another method of gene control in vivo and advance the field of optogenetics.^{24, 25}

The gene with the next highest levels of activation as studied by qRT-PCR was that encoding the cytokine IL6 which showed a 119-fold increase at the laser spot and a 20-fold increase in the adjacent laser region. While Cxcl3 was the only chemokine analyzed with qRT-PCR, the microarrays indicated that there was a large number of members of this group that were up-regulated by 4-fold or more due to laser thermal stress. These included Cxcl2, Cxcl5, Cxcl13, Ccl3, Cxcl1, Ccl7, Ccl12, Ccl4, Ccl9, Ccl2, and Ccr1, and indicate an extreme and broad pro-inflammatory response comprised of a number of immune cell types. Of the 145 up-regulated genes in the laser spot, 11 were chemokines or chemokine related genes. This is not an unexpected finding since chemokines play an important role in regulating processes involved in wound healing including attracting immune cells and keratinocytes to the injury site and regulating epithelialization and angiogenesis.^{26, 27, 28, 29}

While Hspa1a (Hsp70), the source of the promoter for our reporter construct, was up-regulated by 13.5 fold in the laser spot and 2.8 fold in the adjacent laser region, as shown by qRT-PCR, Hspa1a was only the seventh highest up-regulated gene of the ones that we had tested with qRT-PCR. Of the genes found to be elevated in our study, there are a number that could be considered for their role in prolonging cellular function after severe thermal stress. To identify these we performed a meta data analysis to identify genes associated with biological processes that are regarded as relevant for wound healing. These included angiogenesis, apoptosis, inflammation, and general stress response. Although these categories are not hard and fast and there is significant overlap and redundancy within the categories, they serve as a guide for understanding the stress response. A complete functional analysis could be conducted for selected genes in future studies.

In the category of angiogenesis, we found four genes with increased expression in stressed regions, and three genes that were down-regulated in this category, which were seen in the laser spot zone only. These results are shown in Table 2. Serpine1 is the principal inhibitor of tissue plasminogen activator (tPA) and urokinase (uPA), and is therefore an inhibitor of fibrinolysis, which is known to play multiple roles in angiogenesis.³⁰ Serpine 1 was reported to be up-regulated by Cxcl12 stimulation.³¹

Table 2

Genes determined by microarray analysis showing a four-fold or greater up-regulation or downregulation related to angiogenesis.

We also analyzed the category of apoptosis-associated genes, and determined that a total of six genes were up-regulated and nine genes were down-regulated in the laser spot. These results are shown in Table 3. In the apoptosis category, Il6 was analyzed by qRT-PCR and shown to be the second highest up-regulated gene in the set affected by thermal stress. The cytokine Il6 is known to be primarily produced at sites of acute and chronic inflammation, where it is secreted into the serum and induces a transcriptional inflammatory response through interleukin 6 receptor, alpha. Specifically, Il6 induces differentiation of Th17 effector T cells. Il6 activity has also been implicated in keloid formation.³²

Table 3

Genes determined by microarray analysis showing a four-fold or greater up-regulation or downregulation related to apoptosis.

In the inflammation category, we identified 25 genes with a 4-fold increase in the thermal stress areas and eight genes that showed a 4-fold, or greater, decrease in expression. These results are shown in Table 4.

Table 4

Genes determined by microarray analysis showing a four-fold or greater up-regulation or downregulation related to inflammation.

Last, we examined the class of genes associated with stress responses. This process, by far showed the highest number of genes that were increased or decreased. A total of 39 stress response related genes showed increased expression between the two regions of interest, and 28 genes appeared to be decreased in expression within the laser spot. These results are shown in Table 5. Within this process, Il6, Hspa1a, and Hspa4 were up-regulated and qRT-PCR confirmed these observations (Fig. 3).

Table 5

Genes determined by microarray analysis showing a four-fold or greater up-regulation or down regulation related to stress response.

In summary, 145 genes were up-regulated by at least 4-fold in the laser spot and 69 genes were 4-fold up-regulated in the region adjacent to the laser spot. Several of these genes are associated with cytoprotection and also for tissue response to thermal stress. Chemokines, the most common up-regulated genes identified, are in the tissue response category since they are secreted and are likely not involved in cytoprotection. Comparison of the thermally damaged laser spot with the thermally stressed adjacent region revealed differences in gene expression over time. The differential expression in these two regions suggests that there are genes that cannot be activated in regions of high thermal stress but are activated in adjacent regions. This may indicate that transcriptional regulation is differentially affected by heat or that there are factors that act as thermometers and produce a graded response depending on the temperature and duration of heating. The fact that this severe damage at this site did not compromise generalized transcriptional machinery, since selected genes were increased, supports the idea of a graded response corresponding to the extent of stress. A full complement of stress response genes was observed in this region at later time points indicating that they may be essential for cell survival and repair, and may be due to an influx of cells from less damaged regions.

In addition to revealing features of the acute response to thermal injury and possible pathways of tissue repair, the genes in these data sets provide possible regulatory regions for use in creating reporter genes with improved or differential responses to cellular stress and tissue damage. These may be useful in the creation of next generation transgenic reporter mice that would reveal damage to tissues during surgery or other injuries and serve as indicators of the healing response. Thermal control of gene expression can be accomplished by placing promoters from these thermally regulated genes in front of therapeutic genes thus creating genetic constructs whose expression can be controlled from a distance using heat deposition from lasers, focused ultrasound, or other tools. Moreover, these genes and their encoded proteins could be used as therapeutic targets for improving wound healing and repairing burned tissues.