Application of Autofluorescence for Confocal Microscopy to Aid in Archaeoparasitological Analyses

Article information

Korean J Parasitol. 2019;57(6):581-585
Publication date (electronic) : 2019 December 31
doi : https://doi.org/10.3347/kjp.2019.57.6.581
1Pre-Health Pathways, Student Success Center, South Dakota School of Mines & Technology, Rapid City, SD 57701, USA
2Pathoecology and Palynology Laboratory, School of Natural Resources, University of Nebraska-Lincoln, Lincoln, NE 68503, USA
3Department of Agronomy and Horticulture, University of Nebraska-Lincoln, Lincoln, NE 68583, USA
*Corresponding author (johnicamorrow@yahoo.com)
Received 2019 July 31; Revised 2019 September 4; Accepted 2019 October 12.

Abstract

Confocal laser scanning microscopy (CLSM) was used to examine archaeoparasitological specimens from coprolites associated with La Cueva de los Muertos Chiquitos (CMC) located near present-day Durango, Mexico. The eggs for 4 different types of parasites recovered from CMC coprolites were imaged using CLSM to assist with identification efforts. While some of the parasite eggs recovered from CMC coprolites were readily identified using standard light microscopy (LM), CLSM provided useful data for more challenging identifications by highlighting subtle morphological features and enhancing visualization of parasite egg anatomy. While other advanced microscopy techniques, such as scanning electron microscopy (SEM), may also detect cryptic identifying characters, CLSM is less destructive to the specimens. Utilizing CLSM allows for subsequent examinations, such as molecular analyses, that cannot be performed following SEM sample preparation and imaging. Furthermore, CLSM detects intrinsic autofluorescence molecules, making improved identification independent of resource and time-intensive protocols. These aspects of CLSM make it an excellent method for assisting in taxonomic identification and for acquiring more detailed images of archaeoparasitological specimens.

INTRODUCTION

Confocal laser scanning microscopy (CLSM) is a powerful tool that can be used for studying a variety of organisms [110]. Using CLSM is an excellent way to examine the internal and external features of microscopic organisms in detail without compromising the structural integrity of specimens or rendering specimens unusable for further analyses. Such examinations can be useful for taxonomic identifications of archaeoparasitological specimens. Using CLSM techniques for the visualization of parasite eggs does not require staining preparation as these specimens are able to be imaged using the intrinsic properties of the organisms [11]. This is true for both modern and ancient parasite eggs. Herein, we report a novel application of CLSM for the analysis of parasite eggs collected from archaeological source materials. These applications can be applied to future studies of archaeoparasitological materials, including both helminth eggs and arthropod specimens.

MATERIALS AND METHODS

The specimens used for this study were obtained from La Cueva de los Muertos Chiquitos (CMC), a cave in Durango, Mexico, which was utilized by the Loma San Gabriel 1,300 years ago. Coprolites (i.e., desiccated feces) were processed from this site for performing standard archaeoparasitological analysis, which traditionally has included stereomicroscopy and light microscopy (LM). After conducting traditional analyses of these samples, some of the parasite eggs were easily recognizable, while others proved to be more challenging to identify. Thus, select slide-mounted parasite egg specimens from CMC coprolites were further subjected to CLSM to aid in identification efforts and to gain high-quality images of representative specimens [12]. To the authors’ knowledge, this is the first time that CLSM has been used to image archaeoparasitological specimens and the first time that CLSM has been used to assist in taxonomic identification efforts for parasite eggs recovered from coprolites.

Slides were prepared by adding a small amount of processed material to a drop of glycerin onto a glass microscope slide and topping it with a 22×22 mm glass coverslip. Slides were sealed using a clear, commercial nail lacquer and were selected for CLSM based upon parasite egg preservation and parasite egg concentrations [12]. The selected slides contained multiple egg specimens for several different species of parasites.

A Nikon A1 confocal laser scanning microscope (Nikon, Melville, New York, USA) with 4 photomultiplier tubes and transmitted light detector was used to detect greater morphological characters than traditional brightfield microscopy. The A1 was mounted on a Nikon 90i upright compound microscope with Nomarski Interference Contrast optics and coupled with a standard z-step motor. Single images or Z-series images were acquired with a 60×Plan Apo VC water immersion lens 1.2NA objective. Autofluorescence was excited with 4 laser lines of 405, 488, 561, and 640 nm. Emission was detected between 425–475 nm pseudocolored grey, 500–550 nm pseudocolored green, 575–625 nm pseudocolored red, and 650–720 nm, respectively. Images acquisition and analysis of CLSM data was with the Nikon NIS-Elements 4.40 software supplied with the A1.

RESULTS

CLSM was used to capture images of parasite egg specimens. Among those images were photos were of Enterobius vermicularis (Figs. 12), a member of the trematode suborder Echinostomata (Fig. 3), Physaloptera sp. (Figs. 45) and Toxascaris sp. (Figs. 69). Channels 1 and 2 produced the most informative images by themselves; however, combined channel images also demonstrated morphological differences that were informative. The E. vermicularis and Echinostomata specimens had been identified previously, but the CLSM images captured were informative in further supporting identification efforts.

Fig. 1

Nomarski image of Enterobius vermicularis egg recovered from a CMC coprolite (Scale=25 μm).

Fig. 2

Autofluorescence image of Enterobius vermicularis egg recovered from a CMC coprolite (Scale=25 μm).

Fig. 3

Nomarski image of a parasite egg belonging to a trematode within the suborder Echinostomata recovered from a CMC coprolite (Scale=25 μm).

Fig. 4

Nomarski image of a Physaloptera sp. egg recovered from a CMC coprolite (Scale=25 μm).

Fig. 5

Autofluorescence image of a Physaloptera sp. egg recovered from a CMC coprolite (Scale=25 μm).

Fig. 6

Nomarski image of a Toxascaris sp. egg recovered from a CMC coprolite (Scale=25 μm).

Fig. 7

Autofluorescence image of a Toxascaris sp. egg recovered from a CMC coprolite (Scale=25 μm).

Fig. 8

Nomarski image of a Toxascaris sp. egg recovered from a CMC coprolite (Scale=25 μm).

Fig. 9

Autofluorescence image of a Toxascaris sp. egg recovered from a CMC coprolite (Scale=25 μm).

Physaloptera sp. eggs recovered from CMC coprolites measured 45.80×33.46 μm on average (±2.75×2.28 μm). They were oval-shaped with thick outer walls ranging between 4–6 μm in thickness, and the remains of their juvenile worms are coiled within the eggs. The Toxascaris sp. eggs recovered from CMC coprolites measured 78.80×57.59 μm on average (±7.60×7.01 μm). These eggs were ellipsoid, with smooth, thick shells and most contained the remains of juveniles, though some of these juveniles had emerged or were emerging at the time of death. The observable gastrointestinal tract was straight, lacking any bulbs or other diagnostic features, and the bodies of the juveniles measured approximately 220 μm in length. Based on these characteristics, and upon comparisons with the morphological characters and egg size ranges of modern eggs from Ancylostoma spp., Mastophorous muris, Necator americanus, Protospirura spp., Toxascaris leonina, and Toxocara spp., it was determined that these nematode eggs were most similar to Toxascaris leonina.

DISCUSSION

This study demonstrates that CLSM is an excellent tool for archaeoparasitological studies. The CLSM images of these parasite eggs revealed detailed morphological features that were helpful in identification efforts. Many of these subtle anatomical features are less visible during LM analysis of archaeoparasitological specimens, thus using advanced microscopy techniques, such as CLSM, can be useful for determining the taxonomic designations of parasite eggs recovered from archaeological contexts [11,13]. At the time of imaging, Physaloptera sp. and Toxascaris sp. specimens had not yet been identified. The CLSM images of these specimens highlighted morphological details that were less apparent during the LM analyses and aided in identification efforts.

Many of the parasite specimens collected during archaeoparasitological analyses are rare and delicate, much like the archaeological materials from which they are collected. Thus, it is imperative that archaeoparasitological researchers employ care when extracting data from archaeological contexts. Some destruction of these materials is unavoidable. For example, extracting microfossil data from coprolites requires that the coprolite matrix in which these specimens are suspended be destroyed for microfossil recovery. To minimize a loss of data, researchers only use a portion of each coprolite, rather than an entire coprolite, for processing. Coprolite analysts also take many macroscopic and microscopic digital images, keep meticulous notes for later reference, and perform sequential analyses to extract as much data regarding diet and disease as possible [12]. Additionally, when samples contain large amounts of ash or other particulate contaminants that may obscure the view of parasite egg specimens, CLSM may be a useful tool for exposing the features of these specimens as such contaminants do not have autofluorescence

Given the rarity of archaeoparasitological specimens, researchers seek minimally destructive methods to preserve these specimens for subsequent analyses. To gain more detailed images of parasite specimens, scanning electron microscopy (SEM) is often employed. SEM requires specimens to be mounted onto adhesive stubs, and sometimes to undergo critical-point drying followed by coating the specimen in gold-palladium (sputter-coating). SEM specimen preparation techniques render specimens unusable for other types of microscopy and subsequent DNA or other molecular examinations. CLSM examinations are far less destructive to specimens. CLSM does not require permanent mounting, staining, critical-point drying, or sputter-coating prior to microscopy. While specimens that undergo CLSM are exposed to lasers, which cause some destruction on an atomic level, these specimens are still useful for subsequent analyses. This lack of additional specimen preparation prior to imaging makes CLSM well-suited for working with rare/unique specimens and specimens that could be used for further examinations, such as molecular analyses. Parasite eggs that have been imaged using CLSM can be subsequently viewed using LM, remounted in slide media if needed, or extracted for molecular analyses. This flexibility for advanced microscopy without the trade-off of specimen destruction or prevention of subsequent analysis is ideal for rare, delicate, and unique specimens, such as those used in archaeoparasitological studies.

To the authors’ knowledge, this is the first instance of utilizing CLSM to aid in the identification of parasite specimens recovered from archaeological contexts. Future studies of parasite eggs, ectoparasite remains, or other unique specimens recovered from archaeological materials should consider employing CLSM in their efforts to taxonomically identify specimens and collect high-quality images without sacrificing specimens or limiting the ability to perform subsequent analyses on unique specimens.

ACKNOWLEDGMENT

The authors would like to thank Dr. Karl J. Reinhard for access to CMC coprolites and to the Pathoecology and Palynology Laboratory at the University of Nebraska-Lincoln.

Notes

CONFLICT OF INTEREST

The authors declare no conflict of interest related to this study.

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Article information Continued

Fig. 1

Nomarski image of Enterobius vermicularis egg recovered from a CMC coprolite (Scale=25 μm).

Fig. 2

Autofluorescence image of Enterobius vermicularis egg recovered from a CMC coprolite (Scale=25 μm).

Fig. 3

Nomarski image of a parasite egg belonging to a trematode within the suborder Echinostomata recovered from a CMC coprolite (Scale=25 μm).

Fig. 4

Nomarski image of a Physaloptera sp. egg recovered from a CMC coprolite (Scale=25 μm).

Fig. 5

Autofluorescence image of a Physaloptera sp. egg recovered from a CMC coprolite (Scale=25 μm).

Fig. 6

Nomarski image of a Toxascaris sp. egg recovered from a CMC coprolite (Scale=25 μm).

Fig. 7

Autofluorescence image of a Toxascaris sp. egg recovered from a CMC coprolite (Scale=25 μm).

Fig. 8

Nomarski image of a Toxascaris sp. egg recovered from a CMC coprolite (Scale=25 μm).

Fig. 9

Autofluorescence image of a Toxascaris sp. egg recovered from a CMC coprolite (Scale=25 μm).