This protocol provides an overview of procedures for the isolation of RNA for the transcriptomic profiling of lymph node tissues from large animals, including steps in the identification and excision of lymph nodes from livestock and wildlife, sampling approaches to provide consistency across multiple animals, and considerations plus representative results for the post-collection preservation and processing for RNA analysis.
Large animals (both livestock and wildlife) serve as important reservoirs of zoonotic pathogens, including Brucella, Mycobacterium bovis, Salmonella, and E. coli, and are useful for the study of pathogenesis and/or spread of the bacteria in natural hosts. With the key function of lymph nodes in the host immune response, lymph node tissues serve as a potential source of RNA for downstream transcriptomic analyses, in order to assess the temporal changes in gene expression in cells over the course of an infection. This article presents an overview of the process of lymph node collection, tissue sampling, and downstream RNA processing in livestock, using cattle (Bos taurus) as a model, with additional examples provided from the American bison (Bison bison). The protocol includes information about the location, identification, and removal of lymph nodes from multiple key sites in the body. Additionally, a biopsy sampling methodology is presented that allows for a consistency of sampling across multiple animals. Several considerations for sample preservation are discussed, including the generation of RNA suitable for downstream methodologies like RNA-sequencing and RT-PCR. Due to the long delays inherent in large animal vs. mouse time course studies, representative results from bison and bovine lymph node tissues are presented to describe the time course of the degradation in this tissue type, in the context of a review of previous methodological work on RNA degradation in other tissues. Overall, this protocol will be useful to both veterinary researchers beginning transcriptome projects on large animal samples and to molecular biologists interested in learning techniques for in vivo tissue sampling and in vitro processing.
RNA-sequencing analysis of the transcriptome of lymph nodes provides the opportunity to characterize the immune response of animals to a variety of pathogens. While this methodology has been utilized extensively in mice, analyses have recently been expanding into larger mammals1,2. Livestock/large animal lymph nodes can be used to characterize host responses to an infection, not only for their use in vaccine or genetic susceptibility studies and for the identification of targets for drug development, but also as model systems for human studies on zoonotic diseases. For example, in the case of brucellosis (a zoonotic bacterial disease that impacts half a million people around the world each year), despite significantly increased costs, studies in sheep or goats are more relevant to the human infection and human vaccine development than laboratory animal models. Mouse infection models recapitulate the reticuloendothelial system infection but not the characteristic clinical signs3.
In large animal experiments as compared to laboratory animal studies, the process of tissue harvesting necessarily involves a longer delay between the euthanasia and the tissue collection, which presents a potential challenge for the preservation of high-quality RNA. Intact RNA is essential for the generation of biologically relevant transcriptomic data. The generation of high-quality RNA from tissue samples is particularly critical for large animal pathogen studies conducted in containment facilities. Such studies are inherently more difficult to perform as they not only require approved facilities and highly trained personnel but also carry significant financial costs, which, depending on the work, can range from tens to hundreds of thousands of dollars. These types of studies also involve a cross-disciplinary collaboration and cross-disciplinary knowledge for their completion, adding to their complexity. Therefore, training on, development of, and adherence to a streamlined system for the sample collection and preservation provides significant benefits for downstream molecular studies of tissues from infected animals.
The collection of larger lymph nodes presents additional challenges for the tissue collection compared to the similar sampling of murine lymph nodes. The preparation for the sample excision necessitates a basic understanding of the anatomy of the lymph node, including the relevant internal structures. The structure of a lymph node is comprised of lymphoid lobules surrounded by sinuses filled with lymph. These structures are enclosed within a tough, fibrous capsule.4 A lymphoid lobule is the "basic anatomical and functional unit of the lymph node" and is composed of follicles, a deep cortical unit, and medullary cords and sinuses4 (Figure 1A). B and T lymphocytes are home to the follicles and deep cortical units, respectively. These structures provide a 3D scaffold and facilitate the interaction between the lymphocytes and antigen or antigen presenting cells.
Grossly, follicles and deep cortical units can be identified on cut surface as they contain a denser reticular meshwork and appear darker than the sinuses, which are comprised of a more delicate reticular meshwork and appear lighter (Figure 1B). By convention, pathologists refer to the regions of the lymph nodes as the superficial cortex (follicles), the paracortex (deep cortical units) and the medulla (medullary cords and sinuses). A proper examination of all three regions has been deemed as best practice in routine pathological examination guidelines for lymph nodes5. Note that there is a considerable variation in the consistency, size, and color of lymph nodes, even within a single animal. As animals age, their lymph nodes will tend to decrease in size and become firmer than those of younger animals, typically due to an increase in their connective tissue and a reduction of the normal lymphoid structure6,7.
Figure 1. Anatomy of the lymph node. (A) This cartoon image shows the anatomy of the lymph node, depicting key structures. (B) This still image shows a bovine lymph node cut in cross-section. The relevant structures/layers that are visible to the naked eye are highlighted. Please click here to view a larger version of this figure.
Depending on the experimental question, different lymph nodes will be of interest for the collection and analysis. Peripheral lymph nodes are those located deep in the subcutaneous tissue. In cattle, peripheral or superficial lymph nodes often used in clinical and experimental practice include parotid, submandibular, retropharyngeal, prescapular, prefemoral (precrural) and superficial inguinal (supramammary in females, scrotal in males) (Figure 2). In Table 1, the properties of key superficial lymph nodes, as described in the cattle system8, are outlined. Below, some potential lymph node collection plans for infectious bacterial diseases of cattle are presented as a starting point for the investigation.
Brucella abortus/Brucella melitensis: Standard necropsies for B. abortus-infected cattle and B. melitensis-infected goats at the National Animal Disease Center recover supramammary, prescapular, and parotid lymph node tissue, both for the grinding for the bacterial enumeration and for the RNA preparation for the host RNA expression profiling. B. abortus can be regularly recovered in each of these lymph nodes in experimentally infected cattle9. The presence of bacteria in each of these lymph node types can be detected in B. melitensis-infected goats up to at least nine months post-infection using the RNA-based methodologies from our studies (Boggiatto et al., unpublished). Salmonella sp.: The prescapular, subiliac (prefemoral), and mesenteric lymph nodes have been useful during the profiling of cattle carcasses for a Salmonella prevalence10,11,12 and would be of potential interest for transcriptomic studies. E. coli O157:H7: Mesenteric lymph nodes (at the middle small intestine and distal small intestine locations) can be the sites of an occasional recovery of the bacteria in infected calves (but not in infected adult cattle)13. Leptospirosis (Leptospira sp.): A chronic persistence of the bacteria has been observed in the lymph nodes draining the mammary gland14. Mycobacterium bovis: In cattle, the bacteria have been recovered post-experimental infection from the mediastinal and tracheobronchial lymph nodes of calves15. Additionally, lymph node RNA has been utilized to examine large animal host responses to viruses, such as the porcine reproductive and respiratory syndrome virus2. Figure 2 depicts the location of a subset of these major lymph nodes in the cattle body.
Figure 2: Cartoon depicting selected lymph node locations in Bos taurus. The numbered lymph nodes are annotated. Please click here to view a larger version of this figure.
In this paper and the associated video, we present a protocol for the isolation of large animal lymph nodes for RNA studies, designed to be informative for molecular biologists involved in transcriptomic studies of large animal infections. First, we provide an overview of the isolation procedure for the lymph nodes, using sampling from bovine and bison tissues as examples. Paired with this demonstration, as displayed in the video, is a workflow for a reproducible tissue sampling for RNA isolation. Next, we describe important considerations for the processing of an infected lymph node, with a focus on safety, consistency, and RNA quality.
The preparation of RNA from the tissue with an acidified phenol-guanidine isothiocyanate reagent is based on the original method of Chomczynski and Sacchi16,17, with a purification over silica-based spin columns in the presence of chaotropic agents based on the original work of Vogelstein and Gillespie18. We also examine the potential for the recovery of RNA for transcriptomics from cattle lymph nodes preserved by alternative methods. Finally, we explore the impact of the time variable on the RNA quality in large animal necropsies, including a representative experiment depicting the effect of an increase in time between the euthanasia and the sampling on the recovered RNA profile from bison and bovine lymph nodes. This article will be useful not only to molecular biologists but also to veterinary researchers commencing transcriptomic studies.
The animal necropsy procedures depicted here are covered under approved IACUC protocols at the National Animal Disease Center, Ames, IA. All experiments were conducted in accordance with the approved guidelines for animal care and welfare.
1. Pre-planning Before Necropsy
2. Identification and Sampling of Lymph Nodes in Cattle and Bison
Figure 3. Lymph nodes of the bovine head and neck. (A) This cartoon image shows selected lymph nodes of the head and neck of Bos taurus. (B) This image shows the parotid lymph node in cross-section (left) as compared to the parotid salivary gland in cross-section (right). Note the difference in textures between the two tissue types. Please click here to view a larger version of this figure.
3. Sectioning and Storage of Lymph Nodes
4. Processing from RNA Lymph Nodes
CAUTION: Wear a lab coat, gloves, and proper eye protection for the processing steps.
Note: The phenol-based reagent used here is described in the Table of Materials (and the protocol is based on the manufacturer's guidelines)20. The use of alternative phenol-based reagents may necessitate a modification of the procedure, based on the manufacturer's recommendations for the specific product purchased.
5. Alternative Extraction Method from Formalin-fixed, Paraffin-embedded (FFPE) Tissues
Note: Although FFPE tissue preservation does not represent the most robust method of nucleic acid preservation, the protocol presented below can be a way to study some transcriptional changes when other preserved tissues are unavailable.
The use of the considerations presented in this article (steps 1 – 4 of the protocol) will aid in the recovery of RNA from large animal samples that is suitable for a downstream analysis in host gene expression studies. The RNA quality for downstream applications is assessed by multiple standard measures. For spectrophotometry, the A260/A280 ratio provides a measure of the protein contamination, and the A260/A230 ratio provides another means of purity assessment that will detect chemical contaminants such as phenol. In each case, ratios of ~ 2.0 are evidence of high-quality RNA, and decreased ratios are evidence of contamination. Importantly, these ratios do not provide any information about RNA degradation, which can be assessed qualitatively (steps 4.15 – 4.17) and quantitatively (step 4.18, such as through an RNA integrity number or RIN score).
It is important to note that the expected quality level of RNA recovered from lymph node tissue sections is, on average, lower than for RNA recovered from bovine white blood cell samples. In a comprehensive series of RNA extractions from bovine tissues and cell lines, Fleige and Pfaffl30 find that the average RIN (RNA integrity numbers as measured on a Bioanalyzer) vary between < 5 for jejunum and rumen tissue and > 9 for white blood cells and corpus luteum, with lymph node RIN scores falling in the middle at an average of 6.9. In general, Fleige and Pfaffl30 note that solid tissues produce RIN scores ranging from 6 – 8, and that tissues with higher concentrations of connective tissue exhibit a higher mean degradation. The density of connective tissue in the lymph node, plus the intrinsic level of RNases in this tissue type, may be responsible for the inability to consistently recover RNA with RIN scores > 9 from lymph nodes.
However, an example of a Bioanalyzer profile for the RNA recovered from a bison supramammary lymph node using the methodology presented here is displayed in Figure 4A, demonstrating the recovery of RNA with a RIN score of 8.6 (primarily intact and suitable for essentially all downstream applications). RNA generated from this procedure has been used to successfully generate libraries for use in RNA-sequencing; this protocol allows for the regular isolation of RNA samples from bison and bovine lymph nodes with RIN values > 8 (and often > 9). For a sample set of eight extracted RNA samples, the average absorbance ratio at 260 nm/280 nm was 2.1 and at 260 nm/230 nm was 2.1, indicating a low protein contamination and a low contamination with chemicals like phenol, respectively. The average nucleic acid recovery from each extraction was 97 ± 10 µg per ~ 100 mg or a yield of ~ 1 µg RNA/mg of lymph node tissue.
Figure 4. Representative quality traces depicting RNA quality from extraction methodologies. (A) This panel shows a total RNA trace of high-quality RNA generated from a bison lymph node, using the procedure presented in this manuscript. (B) This panel shows a trace of a bovine FFPE-sample selected from Table 4, depicting very degraded RNA. Please click here to view a larger version of this figure.
Due to the challenges associated with the rapid isolation of tissues from large carcasses, especially in the case of sampling from wildlife species, the impact of the time delay between the euthanasia and the placement of the tissue pieces in an RNA preservation solution is of potential concern in the analysis. The information in the literature about the stability of RNA in lymph node tissues, in particular, is limited. Therefore, to provide information about acceptable parameters for tissue collection, the stability of RNA in bison lymph node post-euthanasia was characterized.
For this experiment, time 0 was considered as the time the animal was pronounced dead by the lack of a heartbeat and an absence of a corneal reflex. Following the transport of the carcass and the beginning of necropsy, ~ 15 min had elapsed before the retrieval of the first lymph node sample (15 – 20 min was standard in our observations for the recovery of field animals; time courses will vary depending on the location). The supramammary lymph node was identified, and a small section of the tissue was removed and maintained at room temperature. Sections were subsequently taken at approximately 15 min intervals and transferred to the RNA preservative; in the middle of the time course, a second sample of lymph node was retrieved from the animal for the second set of 4 time points in the series (Figure 5A; closed circles, Figure 5C). RNA was extracted in parallel from the lymph node pieces using the method described above. This 1 h experiment reveals that the lymph node RNA retained the majority of its integrity across the time course, with only slight reductions of the RIN score by the end of the time course (Figure 5B and 5C). Similarly, RNA from bovine prescapular and parotid lymph nodes retained its integrity as measured by the RIN score over ~ 1 h time courses post-mortem (Figure 5C; the animal information is provided in Table 2). Additionally, RNA was extracted from supramammary lymph node sections that were collected 8 h after death, holding whole sections in cell culture media at either room temperature or at 37 °C to simulate the holding time in an animal carcass. Ribosomal RNA was observable even after 8 h holding times (Figure 5D).
Figure 5. RNA quality in bison lymph node samples collected across time courses post-death. (A) This panel shows an experimental overview of a 1 h time course procedure. (B, C) These panels show an examination of the RNA quality for samples taken across a 1 h time course from a supramammary lymph node isolated from an American bison. Gel reflects RNA samples denatured in formamide and separated on a 1% non-denaturing gel. Panel (C) depicts the changes in RIN scores for each sample. The data from additional experiments on bovine prescapular and parotid lymph nodes is overlaid as indicated. (D) This panel shows an example of RNA gel, as described for the gel used in panel (B), for supramammary lymph node samples processed after 8 h of incubation at either room temperature (Lane 1) or at 37 °C (Lane 2) in cell culture media. Please click here to view a larger version of this figure.
These representative findings are consistent with RNA stability results for other tissue types and sources. Table 3 provides a summary of the results of a sample of published papers that have investigated the RNA stability over pre-preservation time courses. Note that only trends from RIN scores and/or rRNA gel observation (total RNA) are included in the table, although some papers provide an additional analysis of mRNA integrity, such as through the determination of ratios of 5' vs. 3' segments of selected RNAs (e.g., Fajardy et al.)31. However, it is important to remember that longer times between the death and sample preservation can result in changes in the RNA expression profiles, as demonstrated, for example, for the placental tissue31. Compared to stable transcripts, more unstable RNAs can be depleted. Therefore, it is important to utilize a rapid, streamlined workflow for the tissue recovery in order to reduce any delay once the animal is available for necropsy, in order to achieve the most biologically valid RNA profiles. It would be a mistake to assume that the presence of intact ribosomal RNA indicates the absence of any changes in the transcriptome profile. Still, the representative results suggest that even with the increased processing times necessary for large animal sampling, it is possible to prepare RNA that is suitable for a gene expression analysis from lymph node samples.
Additionally, the impact of the post-thawing time variable was examined; during this time, RNA is susceptible to degradation from the nucleases present in the tissue. The quality of the RNA samples processed using this protocol with either 0 or 64 min of hold time at room temperature post-thawing at step 4.1 was measured by an RIN score. This experiment demonstrates that the protocol is quite insensitive to the thaw time, making it robust for the processing of multiple samples (Figure 6A).
Figure 6. Additional analysis of RNA quality parameters. (A) This panel shows the RNA quality results for RNA purified either immediately after thawing (0 min) or after holding for 64 min at room temperature prior to the processing. The bars represent the average of 3 tissue pieces for each condition, ± the standard deviation. All tissues were stored in an RNA preservative solution prior to thawing, as described in the protocol. (B) This panel shows a Bioanalyzer trace of a sample from a poorly homogenized lymph node piece containing large sections of connective tissue. The small size of the 28S and 18S peaks, as compared to the peaks in the 5S range, is evident. This can also occur due to the degradation of the RNA, although the relatively flat baseline between the 5S range and the 18S peak is alternatively suggestive of poor extraction; see Avraham, R. et al.48 for additional details. Please click here to view a larger version of this figure.
As a point of comparison to the isolation of RNA from lymph nodes, a trial recovery of RNA from FFPE mesenteric lymph node pieces from cattle was conducted. As described above, the samples were fixed for 1 week in formalin prior to the paraffin embedding, followed by 4 months of storage in paraffin at room temperature. The tissues were sectioned into five 10 µm sections, and using the FFPE extraction procedure, approximately 62 ng/µL of RNA per sample (± 14 ng/µL) was recovered. The absorbance ratios at 260 nm/280 nm averaged 1.9, indicating a product with low levels of protein contamination, although the A260/A230 ratios were unfavorable (Table 4). Note that the RIN scores observed for these samples were very low (< 2), indicating a degradation of the RNA products (Table 4; Figure 4B), consistent with the description of Srinivasan et al.45. In assays utilizing qPCR, typically small sections of RNA, or more specifically cDNA (< 200 bp), are amplified. Therefore, the amplification of small products can still occur from degraded samples, and qPCR analysis can be performed. For example, it was possible to amplify a segment of the ribosomal protein S9 (RPS9) transcript from these FFPE-recovered samples by qPCR. The CT values were consistent across the samples and averaged 19.2 ± 1.8. Keep in mind the limitations that are present when utilizing the FFPE-prepared samples, however, as larger products are not necessarily present, and the degradation may not have occurred at a uniform rate across all samples. Therefore, this material can be used for studies with caveats, but significant limitations are present for any downstream applications like RNA-sequencing.
Lymph Node Type | Location | Length | Larghezza | Regions Drained by Nodes |
Prescapular | Just medial to the shoulder joint; embedded in subcutaneous fat and under a layer of muscle | 1-10 cm | 1.5-2 cm | Skin of neck; shoulder; and skin, muscles, and joints of the lower thoracic limb (ref. 8) |
Prefemoral (also called precrural) | Just dorsal and medial to the stifle, approximately 12-15 cm above the patella | 8-10 cm | 2.5 cm | Skin of the pelvic limb, abdomen, and caudal portions of the thorax (ref. 8) |
Retropharyngeal | Found in the midline dorsal to the pharynx | 4-5 cm | 2-3.5 cm | Tongue, mucous membranes of the oral cavity, gums, lips, hard palate, salivary glands, most of the muscles of the neck |
Parotid | Located subcutaneously ventral to the temporomandibular joint, caudal to masseter muscle (ref. 8) | 6-9 cm | 2-3 cm | Skin, subcutis, most of the muscles of the head, muscles of eye and ear, eyelids, lacrimal gland, rostral portion of nasal cavity |
Submandibular (may be 1-3 present) | Located subcutaneously on the medial aspect of the angle of the mandible, associated with salivary glands | 3-4 cm | 2-3 cm | Muzzle, lips, cheeks, hard palate, rostral part of nasal cavity, tip of tongue, skin and muscle of the head (ref. 8) |
Supramammary (female superficial inguinal, typically 2 present) | Found caudally and dorsally relative to the mammary glands | 6-10 cm | Udder, vulva, vestibule of the vagina, skin on the medial and caudal aspects of the thigh, medial surface of the leg | |
Scrotal (male version of superficial inguinal) | Found below the prepublic tendon within a layer of fat around the neck of the scrotum | 3-6 cm | Scrotum, prepuce, and penis |
Table 1. Overview of bovine superficial lymph nodes.
Animal Description | Location in Manuscript | Age | Sex | Health Status |
Videoed Bison bison | Bison in video–Lymph node recovery | 5-6 yo | Female | Healthy |
Videoed Bos taurus | Bovine in video–Lymph node recovery | 7-8 yo | Castrated male | Healthy |
Bison bison for RNA stability study | Fig. 5A-C | 5-6 yo | Female | Healthy |
Bos taurus A for RNA stability study | Fig. 5C, Fig. 6A | 7-8 yo | Castrated male | Healthy |
Bos taurus B for RNA stability study | Fig. 5C | 7-8 yo | Castrated male | Healthy |
Bos taurus for FFPE quality study | Table 4, Fig. 4B | 0.5 yo | Castrated male | Healthy (control from O157:H7 infection study) |
Note that the methodology has been used on multiple additional cattle, bison, and goat lymph node samples, beyond those that are highlighted here. | ||||
Additionally, we used the same methodology on lymph node collected from a 1.5 mo.-old female calf. |
Table 2. Characteristics of animals used in pilot studies.
Tissue Type | Preservation Method | Holding Conditions | Degradation Conclusion | Reference |
Bovine adipose, skeletal muscle, liver | Snap freezing (liquid N2) | 4 °C, vacuum packaged tissue | Muscle RNA more stable (even out to 8 days of storage); adipose and liver mainly stable to 24 h. as assessed by appearance of rRNA bands | Bahar et al. (2007)32 |
Human colon, colorectal cancer | RNA preservation solution | Room temp. | RIN preserved for 2 h., but subset of genes show changes in expression from 0.5-2 h. | Yamagishi et al. (2014)33 |
Mouse liver, spleen | RNA preservation solution, or snap freezing (dry ice slurry) | Inside the mouse carcass (37 °C) | Spleen samples were stable out to 1.5 h; liver samples exhibited earlier degradation (24% decrease in RIN at 105 min.) | Choi et al. (2016)34 |
Mouse liver | None (Homogenized fresh in guanidinium thiocyanate-phenol-chloroform) | 25 °C, 37 °C | Limited degradation out to 4 h. at 25 °C, but extensive degradation at 37 °C for 4 h. (as observed using RIN scores). | Almeida et al. (2004)35 |
Human ileum | RNA preservation solution, or snap freezing | 4 °C, 37 °C | Generally stable at 1.5 h. at 37 °C; Stable out to 6 h. at 4 °C (as observed using RIN scores). Note that the authors also provide a summary of selected RNA stability resources in Table S1 that can serve as an additional reference for those interested in further review of the tissue RNA integrity literature. | Lee et al. (2015)36 |
Human liver | Snap freezing (liquid N2 or isopentane) | Room temp. | Degradation observed at 1 h. (up to 0.85 ΔRIN); more degradation in smaller samples of liver than in larger samples. | Kap et al. (2015)37 |
Human colorectal cancer | Snap freezing (liquid N2/isopentane) | 4 °C | Degradation observed by 1 h.; RIN score of only 4.2 after 90 min. of delay in freezing time | Hong et al. (2010)38 |
Human liver | RNA preservation solution, Also flash freezing (liquid N2) | Room temp, 4 °C | Samples were stable even out to 1 d. on ice; degradation observed after 1 d. at room temp. (but not after 3 h.; as observed using RIN scores) | Lee et al. (2013)39 |
Horse adipose, skeletal muscle | Snap freezing (liquid N2) | 13 °C | Authors recommend that best integrity for muscle was within 2 h.; adipose preservation within 0.5 h. recommended by authors (as observed by rRNA gel appearance) | Morrison et al. (2014)40 |
Salmon brain, kidney, liver, muscle | RNA preservation solution | Room temp. | Brain RNA stable to 4-8 h., kidney and muscle exhbiit some degradation by 8 h. (gel, RIN score both used) | Seear & Sweeney (2008)41 |
Rabbit connective tissue (ligament, tendon, cartilage) | Snap freezing (liquid N2) | 4 °C, Room temp. | No "overt" degradation out to 96 h. postmortem, as observed by rRNA gel appearance | Marchuk et al. (1998)42 |
Rat brain, lung, heart, liver | Appears to be extracted fresh | Inside the rat carcass held in 20 °C incubator | Highest RNA stability observed in brain (could observe rRNA bands out to 7 days postmortem, although degradation was present), moderate stability in lung and heart, low stability in liver; as observed by rRNA gel appearance | Inoue et al. (2002)43 |
Human tonsil, colon | With and without RNA preservation solution, then snap-frozen | Room temp. (22 °C), 4 °C RNA preservation solution, cold saline, or ice (0 °C) | Stable to 16 h. on ice or in RNA preservation solution; slight degradation at 6 or 16 h. in cold saline or at RT (measured by RIN scores) | Micke et al. (2006)44 |
Table 3. Sample of previous findings on RNA stability in post-mortem tissue samples. The entries represent selected manuscripts from the literature on RNA stability, with a range of tissue types represented, including murine, human biopsy, and veterinary examples. The methods for preservation, the mode of storage pre-extraction, and a brief summary of the results are provided for each example. Unless indicated otherwise, the samples were stored at conditions ranging from ice to 37 °C, followed by snap freezing or an infusion with RNA preservation solution, post-time course (in other words, stability was not being measured in the presence of an RNA preservation solution during the incubation, unless indicated).
Sample ID | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 |
A260/A280 | 1.96 | 1.98 | 1.98 | 1.91 | 1.98 | 1.89 | 1.89 | 1.91 | 1.9 | 1.84 | 1.84 | 1.97 |
A260/A230 | 0.67 | 0.14 | 0.19 | 0.26 | 0.61 | 0.69 | 1.33 | 0.11 | 0.21 | 0.39 | 0.1 | 0.44 |
RIN | 1.6 | 1.1 | 1.3 | 1.2 | 1 | 1.3 | 2 | 1.1 | 1.2 | 1 | 1 | 1 |
Table 4. Representative results from RNA isolated from bovine FFPE mesenteric lymph nodes. The table depicts the results from spectrophotometric and quality analyses from a series of FFPE bovine lymph node samples processed using the method described in this manuscript. In each case, the results reflect highly degraded RNA.
The majority of transcriptomic studies and the associated protocols focus on mouse, rat, or post-mortem human samples. However, investigations in livestock and wildlife provide a wide range of opportunities for the characterization of the immune response to disease, both as applicable to veterinary medicine and, in regard to zoonotic diseases, to human public health. This protocol provided an outline of key considerations for high-integrity RNA extraction from tissues from large animals, such as cattle, bison, goats, and sheep. The size of the animals, as well as the conditions for the sample collection, make the recovery a more extensive process, with a longer post-mortem processing time than for mouse lymph node recovery. Similarly, the large size of these lymph nodes necessitates protocols that recover parallel samples from different animals as well as samples that are representative of the immunological/pathological changes within the lymph node. The suggestions for sample collection in this protocol provide for the recovery of intact RNA as well as for representative profiles based on the sectioning of the lymph node.
As a demonstration of the importance of a standardized sampling strategy and protocol, as presented here, we surveyed 25 papers from the PubMed Central database that characterized the transcriptomes of livestock lymph nodes. One paper indicated the processing of a large lymph node section at one time, one discussed specific laser capture microdissection methods, one mentioned that a "representative sample" was collected from the lymph node, and only one paper46 indicated that the piece of lymph node collected (10 mm3 in size) included both cortex and medulla regions. While other papers noted that small samples (generally 30 – 100 mg) were processed for RNA analysis, 84% of the papers did not mention a sampling strategy for the collection of these tissue pieces. As RNA-sequencing is still relatively expensive, the analysis of multiple sections per lymph node is unlikely to be financially viable in most cases, especially since biological replicate samples are typically prioritized for statistical analysis. By collecting a sample across a wedge of a sagittally sectioned lymph node, RNA from lymph node regions rich in different types of immune cells is captured in all samples. This protocol can, therefore, serve as a reference for a documented and reproducible sampling strategy for lymph node transcriptomics.
In the preparation of RNA from tissues, there are multiple key steps for procedural decision-making. First, the methodological literature is mixed in terms of the use of preservation solutions vs. the use of flash-frozen tissue samples (and subsequent cold-temperature grinding). Especially in the case of large animal necropsies, there are multiple potential procedural benefits to the use of a preservation solution, as incorporated in this protocol. First, tissue samples can be stored during the necropsy in preservation solution without the need to immediately transfer the tubes to liquid nitrogen. Second, the use of a preservation solution provides additional protection prior to sample processing for RNA extraction, particularly if the sample partially or briefly thaws before homogenization. The results in Figure 6A indicate that this protective effect extends to lymph node tissue. In contrast, flash-frozen samples must be maintained in the frozen state until the moment of homogenization in a phenol-containing buffer. Finally, for field necropsies of large animals, where liquid nitrogen is not readily available, samples can be stored in preservation solution until they can be returned to the lab.
Additional advantages of the molecular components of the procedure presented here include the presence of phenol during the initial tissue processing, which serves as a disinfectant during the aerosol-generating process of homogenization for samples from infected animals, and the use of the spin column procedure to remove residual phenol and guanidine isothiocyanate from the sample. The representative results demonstrate that the procedure generates high-quality RNA as assessed by A260/A280 and A260/A230 ratios, gel electrophoresis, and RIN scores, and is robust in the face of time course challenges of livestock and wildlife sampling. The pairing of tissue preservation (e.g., in RNALater), homogenization in phenol-based reagents (e.g., TRIzol), and silica column purification has been successfully utilized in the literature to profile gene expression patterns in ovine abomasal lymph nodes infected with gastrointestinal nematodes46 and in cattle lymph nodes infected with a herpesvirus47, with RIN scores greater than 8 and greater than 7 across all samples, respectively.
In the case of a resulting RNA with unacceptable RIN scores for downstream analysis, the following variables, which are standard for RNA processing, should be assessed: the total processing time post-mortem, the condition of the tissues, the processing time/delay post-thaw, the technique during the RNA extraction, and the RNA handling post-extraction. The total processing time post-mortem should be assessed especially in the case of tissues recovered from animals found dead, as opposed to euthanized animals. As described above, RNA is relatively stable in lymph nodes, but long delays in processing could lead to degradation, especially for unstable transcripts. A confounding time variable could be present if samples are compared between carcasses that have remained in the field for disparate amounts of time. The condition of the tissues should be assessed, because the degradation of tissue integrity, due to pathologic changes associated with infection, may reduce the RNA stability. For example, lower RNA quality has been observed in the placentome of Brucella-infected animals post-abortion (Boggiatto et al., submitted). The processing time/delay post-thaw is mitigated by the use of preservation solutions, as described in this protocol. Be certain that the thickness of the tissue pieces is low enough to allow a proper and rapid penetration of the preservative solution into the tissue (< 5 mm thickness using the preservative mentioned in the Table of Materials). During the RNA extraction, the buffers should be RNase-free and contact with gloves and other contaminated items (RNases are present on the skin) must be avoided. For the grinding of the lymph node tissue, the largest source of potential RNases will be in the tissue itself, but it is beneficial to reduce the introduction of contaminants at all stages of the procedure. To handle the RNA post-extraction, as described in the protocol, aliquot the RNA samples into tubes before the freezing and storage at -80° C, to eliminate the need to freeze-thaw the samples for a quality and quantity analysis.
Low yields in the procedure, in addition to resulting from the degradation of RNA samples, can be due to an inefficient homogenization of lymph node tissue at step 4.3 in the protocol. Note that the incubation in an RNA preservation solution can change the texture of the tissue (increase firmness), although most lymph node tissues dissociated effectively in pilot runs with the large toothed rotor-stator dissociator described here. As noted in step 4.3.1, the homogenization in phenol-based reagent should be repeated if the dissociation is incomplete. Mortar-and-pestle grinding, followed by a resuspension of the ground sample in a phenol-based reagent, is another alternative for laboratories without access to a homogenizer with these specifications. However, a homogenization in disposable tubes presents multiple potential advantages over the grinding of frozen tissue in a mortar and pestle, including a more feasible and shorter workflow for processing multiple samples, an absence of sample loss when grinding, no cleanup, and no potential contact with powered samples, in the case of tissues from infected animals.
Avraham et al.48 describe that a large 5S RNA peak in the final RNA product, paired with a low recovery of 28S and 18S ribosomal RNAs, can be a sign of an incomplete lysis of the cells (which in turn, for lymph node processing, can be due to an incomplete dissociation of the tissue). Figure 6B provides an example of an RNA profile generated from a piece of bovine parotid lymph node that was very high in connective tissue and did not homogenize effectively. RNA yields should be calculated and monitored across samples in a set for analysis to confirm that similar recoveries are obtained per mg of tissue, and samples for direct comparison by RNA-sequencing should be processed in batch, using the same homogenization strategy for all samples. Note that the wedge sampling approach also aids in avoiding a collection of a sample that is exclusively a region of extensive connective tissue.
The authors have nothing to disclose.
The authors would like to thank James Fosse for his excellent work on all videography and video processing; Michael Marti for his excellent work in the generation of digitized cattle images; Lilia Walther for her help with RNA extraction and Bioanalyzer runs; Mitch Palmer and Carly Kanipe for their helpful review and feedback on lymph node images; and the animal care and veterinary staff at the National Animal Disease Center for all of their hard work and assistance with animal husbandry and the preparation for necropsies.
RNA preservation solution (we used RNALater for all experiments) | ThermoFisher | AM7020 | |
1.5 ml or 2 ml polypropylene microcentrifuge tubes | Fisher Scientific | 05-408-129 | |
Disposable scalpels | Daigger Scientific | EF7281 | |
Tissue forceps, rat tooth | Fisher Scientific | 12-460-117 | Other tissue forceps available including curved tip, tapered edge, etc. , depends on user preference |
3 mm punch biopsy needles | Fisher Scientific | NC9949469 | |
Sharps container (small and transportable for necropsy) | Stericycle | 8900SA | 1 qt. size shown here |
Cutting boards or disposable trays | Fisher Scientific | 09-002-24A | Available in a variety of sizes, depends on user preference |
Personal protective equipment | Varies with pathogen (gloves, respirator masks, goggles, etc.) | ||
Phenol-based RNA extraction reagent (we used TRIzol Reagent for all experiments) | ThermoFisher | 15596026 | |
Silica column-based RNA extraction kit (we used the PureLink RNA Mini kit for all experiments) | ThermoFisher | 12183018A | Designed for up to 100 mg tissue |
100% Ethanol (200 proof for molecular biology) | Sigma-Aldrich | E7023 | |
Tissue homogenizer with enclosed homogenization tubes (we used the gentleMACS dissociator for all experiments) | Miltenyi Biotec | 130-093-235 | |
Agarose (General, for gel electrophoresis) | Sigma-Aldrich | A9539 | |
1X TBE | Fisher Scientific | BP24301 | Can also make from scratch in the laboratory |
Deionized formamide | EMD Millipore | S4117 | |
Sodium dodecyl sulfate | Sigma-Aldrich | L3771 | |
Bromophenol blue | Sigma-Aldrich | 114391 | |
Xylene cyanol | Sigma-Aldrich | X4126 | |
EDTA (Ethylenediaminetetraacetic acid) | Sigma-Aldrich | EDS | |
UV-Vis Spectrophotometer (we used the NanoDrop Spectrophotometer) | ThermoFisher | ND-2000 | |
Device for quantitative RNA assessment (we used the Bioanalyzer, with associated components and protocols) | Agilent | G2939BA | |
FFPE RNA extraction kit (we used the RecoverAll Total Nucleic Acid Isolation Kit for Formalin Fixed, Paraffin Embedded Tissue) | ThermoFisher | AM1975 | |
Plastic spreader (L-shaped spreader) | Fisher Scientific | 14-665-231 | Only needed for sterility testing for samples from infected animals |
Necropsy knives | Livestock Concepts | WI-0009209 |