Improved Identiﬁcation and New Records of Dendroctonus Bark Beetles Attacking Pinus contorta in the Subalpine Forest of the Southern Rocky Mountains

: Research Highlights: Atypical and poorly understood attacks by Dendroctonus ruﬁpennis (Kirby) to Pinus contorta Doug. ex Loudon were detected in the southern Rocky Mountains (SRM). The phenomenon is conﬁrmed across all examined area. Its reproduction is described for the ﬁrst time as well as the ﬁrst attacks of D. adjunctus Blandf. in that host. Improved detection and diagnostics of D. ruﬁpennis will allow a simpler, and e ﬃ cient identiﬁcation of the species. It will improve the detection capacity by pest detection specialists and entomologists, which will increase our understanding of the phenomena within and beyond the known range. Background and Objectives: In addition to D. ponderosae Hopk. other Dendroctonus species, sometimes together, attacked P. contorta that grew intermixed with Picea engelmannii in the SRM’ subalpine forest. The identiﬁcation of these beetles was di ﬃ cult. The goal was to improve the detection and identiﬁcation of the species from similar Dendroctonus spp. attacking that host and to uncover biological facts about the phenomena. Materials and Methods: Dendroctonus attacking P. contorta were collected along the entire SRM, their attack signs and behavior were recorded. These characteristics were revised from those in the literature and new characters were introduced and tested. Results: The identiﬁcation of Dendroctonus bark beetles attacking P. contorta in the SRM was improved using revised and new characters including attack signs, attack behavior, and adult beetle characters. An improved identiﬁcation key couplet is presented to e ﬀ ectively distinguish D. murrayanae from D. ruﬁpennis . Conclusions: Simpliﬁed insect identiﬁcations that are both accessible to users with di ﬀ erent levels of expertise and are based on insect characters, their attack pattern, and signs, like the present, improve detection of insects of interest. E ﬃ cient insect detections allow a better understanding of the capabilities they have and the impact they cause to the woodland ecosystems we study, protect, and manage around the globe.


Introduction
In the southern Rocky Mountains (SRM) of Colorado and southern Wyoming, Pinus contorta Douglas (lodgepole pine) grows from 2400 to 3200 m, intermixing with Picea engelmannii Parry ex Engelm (Engelmann spruce) in the subalpine zone, at elevations above 2800 m [1]. In this temperate mountain forest, native Dendroctonus bark beetles kill trees altering forest structure and species composition. Two Dendroctonus bark beetles attack P. contorta natively, D. ponderosae Hopk. (mountain pine beetle) and D. murrayanae Hopk. (lodgepole pine beetle). The magnitude of the impact on their host is different. For instance, during the most recent epidemic, D. ponderosae killed approximately 60% of the mature P. contorta within the SRMs [2,3], whereas D. murrayanae was reported affecting only small patches of trees [4]. The disparity of the beetles' impact reflects their different biologies. While D. ponderosae attacks all Pinus species in the SRM, D. murrayanae only attacks P. contorta. Moreover, different biologies. While D. ponderosae attacks all Pinus species in the SRM, D. murrayanae only attacks P. contorta. Moreover, D. ponderosae occurs throughout the SRMs, while D. murrayanae only occurs above latitude 39.4°, as it appears to be limited to cooler, northern regions [5]. In addition, P. engelmannii has a native Dendroctonus enemy, Dendroctonus rufipennis (Kirby) (North American spruce beetle), with D. ponderosae attacking Picea spp. on rare occasions. With reddish elytra that contrasts with a dark brown head and prothorax, adult D. rufipennis and D. murrayanae closely resemble each other in color, but also in size, shape, and other external characters. The two Dendroctonus are also difficult to distinguish behaviorally since they have similar egg galleries, egg placing patterns, and brood aggregation patterns [6]. Therefore, the distinction between the beetle species is usually based on the infested host [5,7]. Dendroctonus rufipennis populations have been irruptive during the last 20 years, killing large numbers of suitable P. engelmannii in the SRM.
In the SRM, subalpine forest coincides with elevations at which D. ponderosae activity can regularly become attenuated by low temperatures [8]. Consequently, D. ponderosae attacks to P. contorta are seldom documented above 3000 m of elevation [8][9][10]. However, during the last epidemic, D. ponderosae attacks were observed above 3000 m providing the opportunity to study their activity in areas where they occur irregularly. While studying this in the Roosevelt National Forest in northern SRM in Colorado, red-elytra Dendroctonus beetles resembling D. murrayanae and D. rufipennis were attracted to baited (Exobrevicomin-Myrcene-Transverbenol, Synergy Semiochemicals) funnel traps (12-funnel Lindgren) monitoring D. ponderosae activity. Due to their resemblance and the response to D. ponderosae lures, that included one P. contorta tree component, these beetles were difficult to identify to species. Attacks by similar bark beetles were also documented in southern parts of the SRM in Colorado, where D. murrayanae has not been documented. On all occasions, these bark beetles were found in mixed stands of P. contorta with P. engelmannii. Thus, the question of whether it was D. murrayanae or D. rufipennis the species responsible for some of the attacks to P. contorta in the region's subalpine forests became a topic of relevance.
Dendroctonus rufipennis has been reported attacking P. contorta in the SRMs before, from 1944-1949 [11] and in 1957 [12] (Figure 1); however, a taxonomic authority [5,7] contradicted those determinations. The phenomena of D. rufipennis attacks to P. contorta in the SRM may be poorly understood due to the difficulty of separating it from D. murrayanae attacking that host in subalpine forests. In this study, Dendroctonus beetles attacking P. contorta in SRM' subalpine forests of Wyoming and Colorado were examined. The objectives of this study were to (1) improve the identification of Records from the 1940s and 1950s are indicated by stars, and squares indicate records made during this study. P. engelmannii (green) and P. contorta (blue) layers were modified from [13], trees intermix in the dashed areas. Records from the 1940s and 1950s are indicated by stars, and squares indicate records made during this study. P. engelmannii (green) and P. contorta (blue) layers were modified from [13], trees intermix in the dashed areas.

Materials and Methods
Sites in this study were in the SRMs, from southern Wyoming to southern Colorado ( Figure 1). Yellowing trees in the spring or red ones in the fall with pitch tubes were used as evidence of trees infested by Dendroctonus beetles. In these areas, both live and dead adult beetles were collected. Live specimens were collected from live P. contorta as these attacked, while dead specimens were found trapped beneath the tree's bark and on the duff around the tree collar. Specimens were placed individually in 1.5 mL microcentrifuge tubes. In the laboratory, specimens were cleaned in an ultrasonic cleaner (100005, Sper Scientific) using warm water and mounted for examination. Previously determined diagnostic characters [5][6][7][14][15][16][17] were used to revise and determine the best diagnostic characters of collected specimens. Voucher specimens from the Hopkins Collection, Rocky Mountain Station, Fort Collins, CO, and collected from P. contorta included: (n = 5) Rout N. A subsample of red-elytra Dendroctonus from Colorado and Wyoming were selected to examine male genitalia. In these, sex was determined by examining a secondary sexual character, i.e., the granules in the interstriae declivity, which are greatly reduced (nearly absent) in males in contrast to being abundant in females [7,14,15]. Before dissecting, male beetles were softened in warm water for five minutes, after which the abdomen was removed ventrally by pulling it using a pair of forceps posteriorly to the metacoxae to access to the aedeagus. Removed aedeagi were cleared in a solution of 10% KOH heated in a warm bath (55 • C) for 15 min to clear the sclerotized aedeagal capsule eliminating the need of removing the delicate endophallus [18] for its examination. Structures were examined with a Leica M16 stereomicroscope (Leica Microsystems, Castle Rock, CO, USA).

New Records of Dendroctonus spp. Attacking P. contorta in the Southern Rocky Mountains
Previous reports of D. rufipennis attacking P. contorta in the SRM where from Routt N. F., Grand Mesa N. F., and White River N. F. limiting records to North-Central Colorado west of the Continental Divide. Dendroctonus rufipennis was here detected attacking numerous P. contorta in subalpine forests from Medicine Bow N. F. in southern Wyoming and from Roosevelt N. F., Gunnison N. F., and Rio Grande N. F. in Colorado encompassing the entire SRM's latitudinal range ( Figure 1) and the east side of the mountain range. Dendroctonus rufipennis is evidently affecting a larger number of trees than in 1940 and 1957, where it was reported to affect 250 and 140 trees, respectively. These findings make the occurrence of this event more widespread and potentially more impactful than previously reported. Dendroctonus adjunctus Blandf. has never been reported before attacking P. contorta. Attacks of this species were detected on a single site in the Rio Grande N. F. where it was found attacking three P. contorta together with D. rufipennis; therefore, treatment of this species is limited in this manuscript.

Diagnosing Dendroctonus Adult Beetles Attacking P. contorta in Subalpine Forest
The external color of the three Dendroctonus is a simple starting point to separate D. ponderosae from the two red-elytra Dendroctonus. Adult D. ponderosae has an even thorax and elytra color, whereas most adult D. murrayanae and D. rufipennis have a darker thorax contrasting with their reddish elytra ( Figure 2). Although D. adjunctus is also even colored, this species is unique among the four species in having a vertical impression on its mid-upper frons. However, these color differences alone are not useful to diagnose a fraction of older D. rufipennis and D. murrayanae that have black elytra matching their head and thorax. Color should be used in conjunction with the length of dorsal setae, particularly of that in the elytral declivity where the two red-elytra beetles have longer setae than D. ponderosae  Figure 2), these two characters are evident to the naked eye on clean specimens. Low magnifications (< 7X) allow distinguishing the dull surface of the elytral declivity and the clearly impressed (flattened) second and third interstrial space that curve strongly towards the suture in D. ponderosae. This character distinguishes D. ponderosae from D. murrayanae and D. rufipennis and, as previously described [14,15], were referred to as striae II and III [7,17].
Forests 2020, 11, x FOR PEER REVIEW 4 of 11 than D. ponderosae ( Figure 2), these two characters are evident to the naked eye on clean specimens. Low magnifications (< 7X) allow distinguishing the dull surface of the elytral declivity and the clearly impressed (flattened) second and third interstrial space that curve strongly towards the suture in D.
ponderosae. This character distinguishes D. ponderosae from D. murrayanae and D. rufipennis and, as previously described [14,15], were referred to as striae II and III [7,17]. Whereas distinguishing D. ponderosae from the other two species was relatively easy, red-elytra species (i.e., D. murrayanae and D. rufipennis) are difficult to distinguish from each other. An early diagnostic character, the presence of punctures on the posterior half of the pre-episternal (synonyms: preëpisternal, proepisternal) area in D. murrayanae described as absent in D. rufipennis [14] (Figure 3) was examined. This morphological character proved to be confusing since (1) it was poorly defined, (2) its study requires the use of magnifications of 40X, and (3) punctures were present, but were more difficult to see in some D. rufipennis. Another character examined described by Wood [7], was the granules and punctures in the frons. He mentioned that "the relative number of punctures and granules offer the only reliable method of separating D. murrayanae from D. rufipennis." Figure 3. From anterior to posterior, the sides of a Dendroctonus thorax is divided into three areas [14]: (1), pre-episternal (pea), (2) episternal (ea), and (3) epimeral (epima). The character of the relative number of punctures at the posterior half of (pea) near white dashed lines, to distinguish D. murrayanae from D. rufipennis is difficult to use. Pictures by J. Mercado, thorax line drawing adapted from Hopkins [14].
The exoskeletal surfaces of Dendroctonus beetles, including the frons, are covered by semi-circular impressions called punctures, and by blunt cusps called granules, the number of these is never Whereas distinguishing D. ponderosae from the other two species was relatively easy, red-elytra species (i.e., D. murrayanae and D. rufipennis) are difficult to distinguish from each other. An early diagnostic character, the presence of punctures on the posterior half of the pre-episternal (synonyms: preëpisternal, proepisternal) area in D. murrayanae described as absent in D. rufipennis [14] (Figure 3) was examined. This morphological character proved to be confusing since (1) it was poorly defined, (2) its study requires the use of magnifications of 40X, and (3) punctures were present, but were more difficult to see in some D. rufipennis. Another character examined described by Wood [7], was the granules and punctures in the frons. He mentioned that "the relative number of punctures and granules offer the only reliable method of separating D. murrayanae from D. rufipennis." Forests 2020, 11, x FOR PEER REVIEW 4 of 11 than D. ponderosae (Figure 2), these two characters are evident to the naked eye on clean specimens. Low magnifications (< 7X) allow distinguishing the dull surface of the elytral declivity and the clearly impressed (flattened) second and third interstrial space that curve strongly towards the suture in D.
ponderosae. This character distinguishes D. ponderosae from D. murrayanae and D. rufipennis and, as previously described [14,15], were referred to as striae II and III [7,17]. Whereas distinguishing D. ponderosae from the other two species was relatively easy, red-elytra species (i.e., D. murrayanae and D. rufipennis) are difficult to distinguish from each other. An early diagnostic character, the presence of punctures on the posterior half of the pre-episternal (synonyms: preëpisternal, proepisternal) area in D. murrayanae described as absent in D. rufipennis [14] (Figure 3) was examined. This morphological character proved to be confusing since (1) it was poorly defined, (2) its study requires the use of magnifications of 40X, and (3) punctures were present, but were more difficult to see in some D. rufipennis. Another character examined described by Wood [7], was the granules and punctures in the frons. He mentioned that "the relative number of punctures and granules offer the only reliable method of separating D. murrayanae from D. rufipennis." The exoskeletal surfaces of Dendroctonus beetles, including the frons, are covered by semi-circular impressions called punctures, and by blunt cusps called granules, the number of these is never  The exoskeletal surfaces of Dendroctonus beetles, including the frons, are covered by semi-circular impressions called punctures, and by blunt cusps called granules, the number of these is never quantified, but puncture closeness and granule location and their spread are described between similar species. In both D. murrayanae and D. rufipennis, punctures are described as being very close; however, in the center of the frons (between the compound eyes), these are described as "distinct" in D. murrayanae and "largely obliterated" in D. rufipennis [5,7].
Wood [5,7] described that granules in the frons interpuncture space are more clearly separated or "isolated" in D. murrayanae than in D. rufipennis "coarsely granulate," but in this study granules were found isolated and dispersed in D. rufipennis as well. This study found that interpuncture space surfaces in D. rufipennis are usually rougher, making granules and punctures hard to discern, whereas these are usually smoother on D. murrayanae, making granules and punctures more apparent, especially in the middle of the frons. This character was found to be useful separating most D. rufipennis and D. murrayanae specimens, but some D. rufipennis had distinct mid-frons punctures; therefore, its use is recommended in addition to other characters. The smoother interspaces also helped to distinguish most D. murrayanae from D. rufipennis when examining other exoskeletal surfaces dorsally and laterally, such as elytra (Figure 2), from similar angles and at similar magnification. At low magnification (7.1X), examined D. murrayanae specimens in collection boxes appear glossier than those of D. rufipennis ( Figure 2). It is recommended that the state of rough vs. smooth to describe the frons interpuncture space surface in the frons center is examined to help separate these species. The accuracy of this character should be studied further for specimens outside the SRM. A new diagnostic character found in this study was simple to use and works with the examined female D. rufipennis and D. murrayanae specimens. There is a sharp deflection of striae III away from the suture near striae IV and then towards the suture near striae VI in D. rufipennis. This deflection is present in D. murrayanae but it is smooth, making it less distinct ( Figure 4). As described, the character was consistently present on all examined female specimens but not easily seen in some males, and its use in other regions merits further study. In males, or when the above characters are obscure or missing on a specimen in poor condition, the character to examine is the distinctly different endophallus [7] of D. rufipennis and D. murrayanae ( Figure 5). quantified, but puncture closeness and granule location and their spread are described between similar species. In both D. murrayanae and D. rufipennis, punctures are described as being very close; however, in the center of the frons (between the compound eyes), these are described as "distinct" in D. murrayanae and "largely obliterated" in D. rufipennis [5,7]. Wood [5,7] described that granules in the frons interpuncture space are more clearly separated or "isolated" in D. murrayanae than in D. rufipennis "coarsely granulate," but in this study granules were found isolated and dispersed in D. rufipennis as well. This study found that interpuncture space surfaces in D. rufipennis are usually rougher, making granules and punctures hard to discern, whereas these are usually smoother on D. murrayanae, making granules and punctures more apparent, especially in the middle of the frons. This character was found to be useful separating most D. rufipennis and D. murrayanae specimens, but some D. rufipennis had distinct mid-frons punctures; therefore, its use is recommended in addition to other characters. The smoother interspaces also helped to distinguish most D. murrayanae from D. rufipennis when examining other exoskeletal surfaces dorsally and laterally, such as elytra (Figure 2), from similar angles and at similar magnification. At low magnification (7.1X), examined D. murrayanae specimens in collection boxes appear glossier than those of D. rufipennis ( Figure 2). It is recommended that the state of rough vs. smooth to describe the frons interpuncture space surface in the frons center is examined to help separate these species. The accuracy of this character should be studied further for specimens outside the SRM. A new diagnostic character found in this study was simple to use and works with the examined female D. rufipennis and D. murrayanae specimens. There is a sharp deflection of striae III away from the suture near striae IV and then towards the suture near striae VI in D. rufipennis. This deflection is present in D. murrayanae but it is smooth, making it less distinct ( Figure 4). As described, the character was consistently present on all examined female specimens but not easily seen in some males, and its use in other regions merits further study. In males, or when the above characters are obscure or missing on a specimen in poor condition, the character to examine is the distinctly different endophallus [7] of D. rufipennis and D. murrayanae ( Figure 5).   To improve diagnosing adult beetles of the similar red-elytra D. murrayanae and D. rufipennis attacking P. contorta in the SRM, the use of the simplified and improved couplet below is recommended.

Diagnosing Dendroctonus Attacks Characteristics to Subalpine P. contorta
Separating D. rufipennis from D. murrayanae using only morphology is difficult; therefore, to complement adult insect determinations, available behavioral characteristics were reviewed, and a new helpful alternative is presented. These are also helpful in the absence of adult insects. The period and height from the duff of tree attack by the three Dendroctonus species are useful to identify the species. Reddish elytra Dendroctonus (i.e., D. murrayanae and D. rufipennis) attack earlier (June), whereas D. ponderosae attacks later (July and August). In the fall, D. rufipennis move to the lower 60 cm of the tree to overwinter [5], this is the area were D. murrayanae develops, making male genitalia examination needed for accurate species determination at that time. In June, attacks of D. rufipennis and D. murrayanae can be determined by the height at which they attack the tree. Attacks above 60 cm are made solely by D. rufipennis, while the attacks of D. murrayanae concentrate below that, but especially below 20 cm [6]. In July and August, both D. ponderosae and D. rufipennis attack above 60 cm, this requires examining other traits in late August to confirm the attacking insect.
Although Wood [7] suggested pitch tubes could be used to identify the attack of Dendroctonus species, he did not describe them in his monograph of the genus Dendroctonus. The examination of the pitch tubes of beetles attacking above 60 cm made in July and August is recommended here. Pitch tubes that sometimes form a slide on the lower outer border are characteristic of D. rufipennis ( Figure  6). A few days after the attack, these become bulkier than those of D. ponderosae attacking the same tree, which differ as they resemble a perpendicular chimney ( Figure 6). The characteristic sign was tested by predicting whether D. ponderosae or D. rufipennis was the attacking beetle. Out of 26 specimens collected with a chimney type pitch tube present, 58% were D. ponderosae (Table 1). In specimens collected with a slide/bulge-type pitch tube, all were D. rufipennis. The low accuracy predicting D. ponderosae did not occur due to confusion with D. rufipennis but with D. adjunctus, Figure 5. The male genital capsule of D. rufipennis (a) and D. murrayanae (b). An internal structure in the genital capsule, the endophallus, is seen through the median lobe (also inserts lower right corners). The endophallus is diagnostic for the two species when other means have been exhausted. Photos by J. Mercado. Endophallus line drawings adapted from Wood [7].
To improve diagnosing adult beetles of the similar red-elytra D. murrayanae and D. rufipennis attacking P. contorta in the SRM, the use of the simplified and improved couplet below is recommended.

Diagnosing Dendroctonus Attacks Characteristics to Subalpine P. contorta
Separating D. rufipennis from D. murrayanae using only morphology is difficult; therefore, to complement adult insect determinations, available behavioral characteristics were reviewed, and a new helpful alternative is presented. These are also helpful in the absence of adult insects. The period and height from the duff of tree attack by the three Dendroctonus species are useful to identify the species. Reddish elytra Dendroctonus (i.e., D. murrayanae and D. rufipennis) attack earlier (June), whereas D. ponderosae attacks later (July and August). In the fall, D. rufipennis move to the lower 60 cm of the tree to overwinter [5], this is the area were D. murrayanae develops, making male genitalia examination needed for accurate species determination at that time. In June, attacks of D. rufipennis and D. murrayanae can be determined by the height at which they attack the tree. Attacks above 60 cm are made solely by D. rufipennis, while the attacks of D. murrayanae concentrate below that, but especially below 20 cm [6]. In July and August, both D. ponderosae and D. rufipennis attack above 60 cm, this requires examining other traits in late August to confirm the attacking insect.
Although Wood [7] suggested pitch tubes could be used to identify the attack of Dendroctonus species, he did not describe them in his monograph of the genus Dendroctonus. The examination of the pitch tubes of beetles attacking above 60 cm made in July and August is recommended here. Pitch tubes that sometimes form a slide on the lower outer border are characteristic of D. rufipennis (Figure 6). A few days after the attack, these become bulkier than those of D. ponderosae attacking the same tree, which differ as they resemble a perpendicular chimney ( Figure 6). The characteristic sign was tested by predicting whether D. ponderosae or D. rufipennis was the attacking beetle. Out of 26 specimens collected with a chimney type pitch tube present, 58% were D. ponderosae (Table 1). In specimens collected with a slide/bulge-type pitch tube, all were D. rufipennis. The low accuracy predicting D. ponderosae did not occur due to confusion with D. rufipennis but with D. adjunctus, performing undocumented attacks in P. contorta in southern Colorado. It is important to note that soft, sappy pitch tubes that somewhat resemble a slide can be made by D. ponderosae attacking P. contorta at lower elevation forests. This occurs when irruptive populations attack healthy trees with a strong quantitative oleoresin response, but a clear slide is not made by D. ponderosae. This should be used as the first step before verifying the insect and egg gallery and only in subalpine P. contorta/P. engelmannii forest type.
Forests 2020, 11, x FOR PEER REVIEW 7 of 11 performing undocumented attacks in P. contorta in southern Colorado. It is important to note that soft, sappy pitch tubes that somewhat resemble a slide can be made by D. ponderosae attacking P. contorta at lower elevation forests. This occurs when irruptive populations attack healthy trees with a strong quantitative oleoresin response, but a clear slide is not made by D. ponderosae. This should be used as the first step before verifying the insect and egg gallery and only in subalpine P. contorta/P. engelmannii forest type.  Second, the identification accuracy of beetle attacks made above 60 cm increased by examining the length of egg galleries (n = 102). Dendroctonus rufipennis egg galleries averaged 13 cm, whereas those of D. ponderosae were longer than 23 cm, as previously described [5]. In the sampled egg galleries, 59.2% of these measuring over 16 cm in length corresponded to D. ponderosae (n = 16), and no D. rufipennis egg gallery measured over that. Moreover, 11 of the 27 long galleries studied were  Second, the identification accuracy of beetle attacks made above 60 cm increased by examining the length of egg galleries (n = 102). Dendroctonus rufipennis egg galleries averaged 13 cm, whereas those of D. ponderosae were longer than 23 cm, as previously described [5]. In the sampled egg galleries, 59.2% of these measuring over 16 cm in length corresponded to D. ponderosae (n = 16), and no D. rufipennis egg gallery measured over that. Moreover, 11 of the 27 long galleries studied were made by D. adjunctus, making this character useful for separating these two species from D. rufipennis in southern Colorado, although not from D. ponderosae. Dendroctonus rufipennis galleries also have short spurs on the sides along their short length that are used as turning sites for the adult beetle, which are absent in D. ponderosae egg galleries ( Figure 6). The complete development of D. rufipennis adults in P. contorta was first suspected in 2014 from the collections of teneral adults from under the bark in Gunnison N. F. in southern Colorado, and in Medicine Bow N. F. in southern Wyoming where these were again collected from the same tree in July 2015 when a dead pupa was found. In mid-July of 2016, standing, live P. contorta in northern Colorado contained 12 D. rufipennis adults initiating galleries-three of which had laid eggs, which confirmed reproduction initiation attempts by the species. In about the same date, adults D. rufipennis were seen emerging a P. contorta in the Medicine Bow N. F. and simultaneously a P. contorta located 10 m from it was being attacked by D. rufipennis. Since there were no other trees with activity within a 30 m radius from these two trees, re-attack to P. contorta by D. rufipennis in that forest is suspected. As eggs, pupae, and teneral adults have been found under the bark of P. contorta reproduction in this host is considered confirmed from the SRM P. contorta/P. engelmannii subalpine forest.
Red-elytra Dendroctonus specimens collected from the 1940 s D. rufipennis epidemic in Colorado (Wygant, White River N. F., 1947), were examined. These beetle specimens resembled D. murrayanae in their color pattern, but the examination of the male genitalia confirmed specimens represented D. rufipennis, confirming their prior attack to P. contorta in SRM.

Discussion
Although, previous reports of D. rufipennis attacking P. contorta in the SRM exist, there remained uncertainty about their veracity. As discussed in his review of the genus Dendroctonus, Wood [7] examined some of the red-elytra Dendroctonus specimens reported attacking P. contorta in the 1940s. On all suspected cases of D. rufipennis attacks to P. contorta, he determined that the insect involved was D. murrayanae [5,7]. However, it is unclear whether the specimens he studied were the same that Massey and Wygant [11] had determined to be D. rufipennis [19]. An issue with Massey and Wygant [11] is that they only report using the characters described by Hopkins [14] to diagnose D. rufipennis from D. murrayanae. These characters were considered insufficient to separate these species by Wood [7] without studying the male genitalia (endophallus). This insufficiency was confirmed in this study as well, as all red-elytra beetle examined from 2010 to 2016 were incorrectly identified as D. murrayanae using the key in [14].
Although it is possible Massey and Wygant [11] knew of an effective way to separate the two red-elytra Dendroctonus, this was not effectively expressed in their report. Therefore, characters and keys referred by them should only be used by expert taxonomists of this group of beetles and even then, with great care and understanding of their limitations. Consistently with Wood [7], it is recommended that careful examination of the male' endophallus is used as the best approach to separate these two species when using adult morphology alone, especially when the newly described elytral striae number three character is confusing or missing. However, apart from the endophallus only we found that Wood's [5,7] key couplet describing the clarity of the punctures on the frons center offered diagnostic utility.
There are still questions regarding the activity of Dendroctonus bark beetles in subalpine P. contorta/ P. engelmannii forest across their distribution. First, why is D. rufipennis attacking this nonhost in the SRMs? Schmid and Frye [19] suggested that under outbreak conditions, Dendroctonus species can attack nontypical hosts in the absence of suitable primary hosts. In other forests where P. contorta and P. engelmannii intermix, D. ponderosae has opportunistically attacked and developed in P. engelmannii [20] or the hybrid Picea engelmannii × glauca [21]. Attacks by single D. ponderosae pairs to P. engelmannii were also observed near one of this study' sites in northern Colorado. However, there were suitable